Multifocal lens having a progressive optical power region and a discontinuity

ABSTRACT

Embodiments of the present invention relate to a multifocal lens having a diffractive optical power region and a progressive optical power region. Embodiments of the present invention provide for the proper alignment and positioning of each of these regions, the amount of optical power provided by each of the regions, the optical design of the progressive optical power region, and the size and shape of each of the regions. The combination of these design parameters allows for an optical design having less unwanted astigmatism and distortion as well as both a wider channel width and a shorter channel length compared to conventional PALs. Embodiments of the present invention may also provide a new, inventive far-intermediate distance zone and may further provide for increased vertical stability of vision within a zone of the lens.

CROSS REFERENCE TO RELATED APPLICATIONS

This application is a continuation-in-part of U.S. Ser. No. 11/964,030 filed on 25 Dec. 2007 and entitled “Multifocal Lens Having a Progressive Optical Power Region and a Discontinuity”, which is incorporated herein by reference in its entirety.

This application claims priority from and incorporates by reference in their entirety the following provisional applications:

-   -   U.S. Ser. No. 60/906,211 filed on 29 Mar. 2007 and entitled         “Composite Advanced Progressive Addition Lens having a         Discontinuity”;     -   U.S. Ser. No. 60/924,975 filed on 7 Jun. 2007 and entitled         “Refined Toric & Spherical Curvatures Associated with a Low Add         Power Contributing Progressive Lens Region”;     -   U.S. Ser. No. 60/935,226 filed on 1 Aug. 2007 and entitled         “Combined Optics for Correction of Near and Intermediate         Vision”;     -   U.S. Ser. No. 60/935,492 filed on 16 Aug. 2007 and entitled         “Diamond Turning of Tooling to Generate Enhanced Multi-Focal         Spectacle Lenses”;     -   U.S. Ser. No. 60/935,573 filed on 17 Aug. 2007 and entitled         “Advanced Lens with Continuous Optical Power”;     -   U.S. Ser. No. 60/956,813 filed on 20 Aug. 2007 and entitled         “Advanced Multifocal Lens with Continuous Optical Power”; and     -   U.S. Ser. No. 60/970,024 filed on 5 Sep. 2007 and entitled         “Refined Enhanced Multi-Focal”.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to multifocal ophthalmic lenses, lens designs, lens systems, and eyewear products or devices utilized on, in or about the eye. More specifically, the present invention relates to multifocal ophthalmic lenses, lens designs, lens systems, and eyewear products which, in most cases, reduce unwanted distortion, unwanted astigmatism, and vision compromises associated with Progressive Addition Lenses to a very acceptable range for a wearer.

2. Description of the Related Art

Presbyopia is the loss of accommodation of the crystalline lens of the human eye that often accompanies aging. This loss of accommodation first results in an inability to focus on near distance objects and later results in an inability to focus on intermediate distance objects. The standard tools for correcting presbyopia are multifocal ophthalmic lenses. A multifocal lens is a lens that has more than one focal length (i.e., optical power) for correcting focusing problems across a range of distances. Multifocal ophthalmic lenses work by means of a division of the lens's area into regions of different optical powers. Typically, a relatively large area located in the upper portion of the lens corrects for far distance vision errors, if any. A smaller area located in the bottom portion of the lens provides additional optical power for correcting near distance vision errors caused by presbyopia. A multifocal lens may also contain a region located near the middle portion of the lens, which provides additional optical power for correcting intermediate distance vision errors. Multifocal lenses may be comprised of continuous or discontinuous surfaces that create continuous or discontinuous optical power.

The transition between the regions of different optical power may be either abrupt and discontinuous, as is the case with bifocal and trifocal lenses, or smooth and continuous, as is the case with Progressive Addition Lenses. Progressive Addition Lenses are a type of multifocal lens which comprises a gradient of continuously increasing positive dioptric optical power from the far distance zone of the lens to the near distance zone in the lower portion of the lens. This progression of optical power generally starts at or near what is known as the fitting cross or fitting point of the lens and continues until the full add power is realized in the near distance zone of the lens. Conventional and state-of-the-art Progressive Addition Lenses utilize a surface topography on one or both exterior surfaces of the lens shaped to create this progression of optical power. Progressive Addition Lenses are known within the optical industry when plural as PALs or when singular as a PAL. PALS are advantageous over traditional bifocal and trifocal lenses because they can provide a user with a lineless, cosmetically pleasing multifocal lens with continuous vision correction and no perceived image break as the user's focus transitions from objects at a far distance to objects at a near distance or vice versa.

While PALs are now widely accepted and in vogue within the United States and throughout the world as a correction for presbyopia, they also have serious vision compromises. These compromises include, but are not limited to, unwanted astigmatism, distortion, and swim. These vision compromises may affect a user's horizontal viewing width, which is the width of the visual field that can be seen clearly as a user looks from side to side while focused at a given distance. Thus, PALs may have a narrow horizontal viewing width when focusing at an intermediate distance, which can make viewing a large section of a computer screen difficult. Similarly, PALs may have a narrow horizontal viewing width when focusing at a near distance, which can make viewing the complete page of a book or newspaper difficult. Far distance vision may be similarly affected. PALs may also make it difficult for a wearer to play sports due to the distortion of the lenses. In addition to these limitations, many wearers of PALs experience an unpleasant effect known as visual motion (often referred to as “swim”) due to the distortion that exists in each of the lenses. In fact, many people refuse to wear such lenses because of the discomfort from this effect.

When considering the near distance optical power needs of a presbyopic individual, the amount of near distance optical power required is inversely proportional to the amount of accommodative amplitude (near distance focusing ability) the individual has left in his or her eyes. Generally, as an individual ages the amount of accommodative amplitude decreases. Accommodative amplitude may also decrease for various health reasons. Therefore, as one ages and becomes more presbyopic, the optical power needed to correct one's ability to focus at a near distance and an intermediate distance becomes stronger in terms of the needed dioptric optical power. The near and intermediate distance optical power is usually stated in terms of an “add power” or “additive optical power”. An add power is the amount of optical power over the far distance vision correction. Add power usually refers to the optical power added to the far distance vision correction to achieve proper near distance vision correction. For example, if one has −1.00D of optical power correction for far distance viewing and +2.00D of near distance add power such an individual has +1.00D of optical power correction for near distance viewing.

By comparing the different near distance add power needs of two individuals, it is possible to directly compare each individual's near point focusing needs. By way of example only, an individual 45 years old may need +1.00D of near distance add power to see clearly at a near point distance, while an individual 80 years old may need +2.75D to +3.50D of near distance add power to see clearly at the same near point distance. Because the degree of vision compromises in PALs increases with dioptric add power, a more highly presbyopic individual will be subject to greater vision compromises. In the example above, the individual who is 45 years of age will have a lower level of distortion and wider intermediate distance and near distance vision zones associated with his or her lenses than the individual who is 80 years of age. As is readily apparent, this is the complete opposite of what is needed given the quality of life issues associated with being elderly, such as frailty or loss of dexterity. Prescription multifocal lenses that add compromises to vision function and inhibit safety are in sharp contrast to lenses that make lives easier, safer, and less complex.

By way of example only, a conventional PAL with a +1.00D near distance add power may have approximately 1.00D or less of unwanted astigmatism. However, a conventional PAL with a +2.50D near distance add power may have approximately 2.75D or more of unwanted astigmatism while a conventional PAL with a +3.25D near distance add power may have approximately 3.75D or more of unwanted astigmatism. Thus, as a PAL's near distance add power increases (for example, a +2.50D PAL compared to a +1.00D PAL), the unwanted astigmatism found within the PAL increases at a greater than linear rate.

More recently, a double-sided PAL has been developed which has a progressive addition surface topography placed on each external surface of the lens. The two progressive addition surfaces are aligned and rotated relative to one another to not only give the appropriate total additive near distance add power required, but also to have the unwanted astigmatism created by the PAL on one surface of the lens counteract some of the unwanted astigmatism created by the PAL on the other surface of the lens. Even though this design reduces the unwanted astigmatism and distortion for a given near distance add power as compared to traditional PALs, the level of unwanted astigmatism, distortion, and other vision compromises listed above still causes serious vision problems for certain wearers.

Other multifocal lenses have been developed which provide for the placement of continuous and/or discontinuous optical elements in optical communication with one another. However, these lenses have not realized an optimal placement and alignment of the continuous and/or discontinuous elements. These lenses have also failed to realize an optimal optical power distribution in the optical elements placed in optical communication. Therefore, these lenses typically have one or more perceived image breaks, prismatic image jump, cosmetic issues, surface discontinuities, poor vision ergonomics, and/or an optical power gradient that is too steep. These issues typically translate into visual fatigue, eyestrain, and headaches for a wearer of these lenses. These lenses have also failed to realize an upper far-intermediate distance zone, a far-intermediate zone having a plateau of optical power, and/or an intermediate zone having a plateau of optical power.

Therefore, there is a pressing need to provide a spectacle lens and/or eyewear system that satisfies the vanity needs of presbyopic individuals and at the same time corrects their presbyopia in a manner that reduces distortion and blur, widens the horizontal viewing width, allows for improved safety, and allows for improved visual ability when playing sports, working on a computer, and reading a book or newspaper.

SUMMARY OF THE INVENTION

In an embodiment of the present invention, an ophthalmic lens may have a far distance zone. The ophthalmic lens may include a diffractive optical power region for providing a first incremental add optical power. The ophthalmic lens may further include a discontinuity located between the far distance zone and the diffractive optical power region. The ophthalmic lens may further include a progressive optical power region for providing a second incremental add power, wherein at least a portion of the diffractive optical power region and the progressive optical power region are in optical communication such that the first incremental add power and the second incremental add power together provide a near distance add power for a user.

BRIEF DESCRIPTION OF THE DRAWINGS

Embodiments of the invention will be understood and appreciated more fully from the following detailed description in conjunction with the figures, which are not to scale, in which like reference numerals indicate corresponding, analogous or similar elements, and in which:

FIGS. 1A-13B show different lenses either having a perceived image break or not having a perceived image break according to embodiments of the present invention;

FIG. 14A shows a view of the front surface of a lens having two optical power regions and a blend zone according to an embodiment of the present invention;

FIG. 14B shows a view of the front surface of a lens having two optical power regions and a blend zone according to an embodiment of the present invention;

FIG. 14C shows a view of the back surface of the lens of FIG. 14A or FIG. 14B having a progressive optical power region below a fitting point of the lens according to an embodiment of the present invention;

FIG. 14D shows a view of the back surface of the lens of FIG. 14A or FIG. 14B having a progressive optical power region at or near a fitting point of the lens according to an embodiment of the present invention;

FIG. 14E shows a cross-sectional view of the lens of FIGS. 14A and 14C taken through the center vertical line of the lens according to an embodiment of the present invention;

FIG. 14F shows the lens of FIGS. 14A and 14C from the front showing the placement and optical alignment of the optical power regions on the front and back surfaces of the lens according to an embodiment of the present invention;

FIG. 14G shows the lens of FIGS. 14B and 14C from the front showing the placement and optical alignment of the optical power regions on the front and back surfaces of the lens according to an embodiment of the present invention;

FIG. 15A shows a view of the front surface of a lens having two optical power regions and a blend zone according to an embodiment of the present invention;

FIG. 15B shows a view of the back surface of the lens of FIG. 15A having a progressive optical power region below a fitting point of the lens according to an embodiment of the present invention;

FIG. 15C shows a lens having a surface which is the mathematical combination of the surface of FIG. 15A and the surface of FIG. 15B according to an embodiment of the present invention;

FIG. 15D shows a diagram pictorially explaining how the surfaces of FIGS. 15A and 15B are combined to form the surface of FIG. 15C according to an embodiment of the present invention;

FIG. 16 shows an add power gradient as measured by a Rotlex Class Plus™ trademarked by Rotlex for an Essilor Physio™ lens trademarked by Essilor, an Essilor Ellipse™ lens trademarked by Essilor, and a Shamir Piccolo™ lens trademarked by Shamir Optical each having a near distance add power of +1.25D according to an embodiment of the present invention;

FIG. 17 shows measurements taken from the fitting point down the channel of the add power found in the three lenses of FIG. 16 as measured by a Rotlex Class Plus™ according to an embodiment of the present invention;

FIG. 18 shows measurements taken from the fitting point down the channel of the add power found in embodiments of the present invention in which a mostly spherical power region having an optical power of +1.00D is placed in optical communication with the lenses of FIG. 16;

FIG. 19 shows an add power gradient for both an embodiment of the present invention on the left and an Essilor Physio™ lens on the right as measured by a Rotlex Class Plus™;

FIG. 20 shows measurements taken from the fitting point down the channel of the add power found in the two lenses of FIG. 19 as measured by a Rotlex Class Plus™ according to an embodiment of the present invention;

FIG. 21 shows four regions of a lens: a far distance zone, an upper far-intermediate distance zone, an intermediate distance zone, and a near distance zone according to an embodiment of the present invention;

FIGS. 22-23 show the optical power along the center vertical mid-line of embodiments of the present invention including a progressive optical power region connecting the far distance zone to the near distance zone;

FIG. 24-26 shows the optical power along the center vertical mid-line of embodiments of the present invention including a mostly spherical power region, a discontinuity, and a progressive optical power region connecting the far distance zone to the near distance zone;

FIGS. 27A-27C show embodiments of the present invention having a blend zone with a substantially constant width located at or below a fitting point of the lens;

FIGS. 28A-28C shows embodiments of the present invention having a blend zone including a portion with a width of substantially 0 mm (thereby providing a transition in this portion similar to a lined bifocal) located at or below a fitting point of the lens; and

FIGS. 29A-29D show methods of manufacturing a composite lens according to embodiments of the present invention.

DESCRIPTION OF THE PREFERRED EMBODIMENT

Many ophthalmological, optometric, and optical terms are used in this application. For the sake of clarity, their definitions are listed below:

Add Power: Add power represents the additional plus optical power required for near distance vision and/or intermediate distance vision. It is most commonly prescribed for presbyopia when the normal accommodative power of the eye is no longer sufficient to focus on near distance or intermediate distance objects. It is called an “add” power, because it is in addition to the far distance optical power of a lens. For example, if an individual has a far distance viewing prescription of −3.00D and a +2.00D add power for near distance viewing then the actual optical power in the near distance portion of the multifocal lens is the sum of the two powers, or −1.00D. Add power is sometimes referred to as plus optical power or additive optical power. Add power may also refer to the add power in the intermediate distance portion of the lens and is called the “intermediate distance add power”. Typically, the intermediate distance add power is approximately 50% of the near distance add power. Thus, in the example above, the individual would have +1.00D add power for intermediate distance viewing and the actual total optical power in the intermediate distance portion of the multifocal lens would be −2.00D.

Blend Zone: A zone which transitions the optical power difference across at least a portion of an optical power discontinuity of a lens, where the discontinuity is located between a first optical power and a second optical power. The difference between the first and second optical powers may be caused, for example, by different surface topographies or by different indices of refraction. The optical power transitions continuously from the first optical power to the second optical power across the blend zone. When diffractive optics are used, the blend zone can include blending the optical efficiency of the peripheral region of the diffractive optics. A blend zone is utilized for cosmetic enhancement reasons. A blend zone is typically not considered a usable portion of the lens due to its poor optics. A blend zone is also known as a transition zone.

Channel: The region of a lens defined by increasing plus optical power, centered by the umbilic of the lens, which extends from the far distance zone to the near distance zone and is free of unwanted astigmatism greater than 1.00D. For a Progressive Addition Lens this optical power progression starts approximately in an area of the lens known as the fitting point and ends in the near distance zone. However, in embodiments of the present invention which have a progressive optical power region, the channel may start between approximately 4 mm and approximately 10 mm below the fitting point. The channel is sometimes referred to as the corridor.

Channel Length: The channel length is the distance measured from the defined start of the channel where the optical power first begins to increase to the location in the channel where the add power is within approximately 85% of the specified near distance viewing power of the lens. For a PAL, the channel typically starts at or near the fitting point.

Channel Width: The narrowest portion of the channel bounded by an unwanted astigmatism that is above approximately 1.00D. This definition is useful when comparing lenses, due to the fact that a wider channel width generally correlates with less blur, less distortion, better visual performance, increased visual comfort, and easier adaptation to the channel for the wearer.

Continuous Optical Power: Optical power that is either substantially constant or that changes in a manner that does not create a perceived image break.

Continuous Surface: A refractive surface that does not cause a perceived image break. A continuous surface can be external or internal to the lens. If internal, it would have a different index of refraction than the material adjacent to it. An example of a continuous surface is the surface of a substantially spherical lens or a Progressive Addition Lens.

Contour Maps: Plots that are generated from measuring and plotting the optical power changes and/or the unwanted astigmatic optical power of a lens. A contour plot can be generated with various sensitivities of astigmatic optical power thus providing a visual picture of where, and to what extent a lens possesses unwanted astigmatism as an effect due to its optical design. Analysis of such maps can be used to quantify the channel length, channel width, reading width and far distance width of a lens. Contour maps may be referred to as unwanted astigmatic power maps, sphere power maps, mean power maps, add power maps, or power error maps. These maps can also be used to measure and portray optical power in various parts of the lens.

Conventional Channel Length: Due to aesthetic concerns or trends in eyewear fashion, it may be desirable, due to frame styles, to have a lens that is foreshortened vertically to fit the frame. In such a lens, to deliver sufficient near distance vision, the channel is naturally also shortened. Conventional channel length refers to the length of a channel in a non-foreshortened lens. These channel lengths are usually, but not always, approximately 15 mm or longer. Generally, a longer channel length means a wider channel width and less unwanted astigmatism compared to PALs with a shorter channel length.

Discontinuity: A discontinuity is an optical power change or a surface change that results in a perceived image break for a user. A discontinuity may be caused by a step up or a step down in optical power between two regions of a lens. For example, a discontinuity of 0.10D refers to a step up or down of 0.10D between two regions of a lens.

Discontinuous Optical Power: Optical power that changes in a manner that creates a perceived image break.

Discontinuous Surface: A surface that causes a perceived image break. A discontinuous surface can be external or internal to the lens. If internal, it would have a different index of refraction than the material adjacent to it. By way of example only, a discontinuous surface is the surface of a lined bifocal lens where the surface changes from the far distance zone to the near distance zone of the lens.

Dynamic lens: A lens with an optical power that is alterable with the application of electrical energy, mechanical energy, or force. The optical power of a dynamic lens is alterable without additional grinding or polishing. Either the entire lens may have an alterable optical power, or only a portion, region, or zone of the lens may have an alterable optical power. The optical power of such a lens is dynamic or tunable such that the optical power can be switched between two or more optical powers. One of the optical powers may be that of substantially no optical power. Examples of dynamic lenses include electro-active lenses, electrical meniscus lenses, a lens having one or more mechanically moving parts, or a lens made from a conformable membrane such as a gas lens or a fluid lens. A dynamic lens may also be referred to as a dynamic optic or a dynamic optical element. A dynamic lens may also be referred to as a transmissive adaptive optic or lens.

Far-Intermediate Distance Zone: The portion or region of a lens containing an optical power which allows a user to see clearly at a far-intermediate distance. The far-intermediate distance zone may be located between the far distance zone and the intermediate distance zone of a lens, in which case it is referred to as the “upper far-intermediate distance zone”. It may also be located below the near distance zone of the lens, in which case it is referred to as the “lower far-intermediate distance zone”. The far-intermediate distance zone may also be referred to as a far-intermediate vision zone.

Far-Intermediate Distance: The distance to which one looks, by way of example only, when viewing to the far edge of one's desk. This distance is usually, but not always, considered to be between approximately 29 inches and approximately 5 feet from the eye and in some cases may be between approximately 29 inches and approximately 10 feet from the eye. The far-intermediate distance may also be referred to as a far-intermediate viewing distance or a far-intermediate distance point.

Far Distance Reference Point: A reference point located approximately 4 mm to approximately 8 mm above the fitting cross where the far distance prescription or far distance optical power of a PAL can be easily measured.

Far Distance Zone: The portion or region of a lens containing an optical power which allows a user to see clearly at a far distance. The far distance zone may also be referred to as the far vision zone.

Far Distance Width: The narrowest horizontal width within the far distance viewing portion of the lens, approximately 4 mm to approximately 8 mm above the fitting point, which provides clear, mostly blur-free correction with an optical power within 0.25D of the wearer's far distance optical power correction.

Far Distance: The distance to which one looks, by way of example only, when viewing beyond the edge of one's desk, when driving a car, when looking at a distant mountain, or when watching a movie. This distance is usually, but not always, considered to be greater than approximately 5 feet from the eye and in some cases may be greater than approximately 10 feet from the eye. “Far distance” is not to be confused with far infinity which is approximately 20 feet or further from the eye. At far infinity, the eye's accommodative system is fully relaxed. The optical power provided in one's optical prescription to correct for approximately 5 feet (or 10 feet) from the eye or greater is typically not significantly different from the optical power needed to correct for approximately 20 feet from the eye. Therefore, as used herein, far distance refers to distances approximately 5 feet (or 10 feet) from the eye and greater. The far distance may also be referred to as far viewing distance or a far distance point.

Fitting Cross/Fitting Point: A reference point on a lens that represents the approximate location of a wearer's pupil when looking straight ahead through the lens once the lens is mounted in an eyeglass frame and positioned on the wearer's face. The fitting cross/fitting point is usually, but not always, located approximately 2 mm to approximately 5 mm vertically above the start of the channel. The fitting cross may have a very slight amount of plus optical power ranging from just over +0.00D to approximately +0.12D. In some cases, this point or cross may be ink-marked on the lens surface to provide an easily viewable reference point for measuring and/or double-checking the fitting of the lens relative to the pupil of the wearer. The mark is easily removed upon dispensing the lens to the wearer.

Hard or Soft Progressive Addition Region: A progressive addition zone with a fast or slow rate of optical power change or astigmatic power change is referred to as a hard or soft progressive addition region, respectively. A lens that contains mostly fast rates of change may be referred to as a “hard progressive addition lens”. A lens that contains mostly slow rates of change may be referred to as a “soft progressive addition lens”. PALs may contain both hard and soft zones depending on the corridor length chosen, add power needed, and the designer's mathematical tools.

Hard Progressive Addition Lens: A Progressive Addition Lens with a less gradual, steeper transition between the far distance correction and the near distance correction. In a hard PAL, the unwanted distortion may be below the fitting point and not spread out into the periphery of the far distance region of the lens. A hard PAL may, in some cases, also have a shorter channel length and a narrower channel width. A “modified hard Progressive Addition Lens” is a PAL which comprises a slightly modified hard PAL optical design having one or more characteristics of a soft PAL such as: a more gradual optical power transition, a longer channel, a wider channel, more unwanted astigmatism spread out into the periphery of the lens, and less unwanted astigmatism below the fitting point.

Horizontal Stability of Optical Power: A region or zone of a lens that has mostly constant optical power across the horizontal width of the region or zone. Alternatively, the optical power change may be an average of approximately 0.05D per millimeter or less across the horizontal width of the region or zone. As another alternative, the optical power change may be an average of approximately 0.10D per millimeter or less across the horizontal width of the region or zone. As a final alternative, the optical power change may be an average of approximately 0.20D per millimeter or less across the horizontal width of the region or zone. The region or zone may have a horizontal width of approximately 1 mm or greater. As an alternative, the region or zone may have a horizontal width of approximately 1 mm to approximately 3 mm or greater. As a final alternative, the region or zone may have a horizontal width of approximately 2 mm to approximately 6 mm or greater. The region or zone may be the far distance zone, the upper far-intermediate distance zone, the intermediate distance zone, the near distance zone, the lower far-intermediate distance zone, or any other region of the lens.

Horizontal Stability of Vision: A region or zone of a lens is said to have horizontal stability of vision if the region or zone has mostly constant, clear vision as a user looks left and right across the region or zone. The region or zone may have a horizontal width of approximately 1 mm or greater. As an alternative, the region or zone may have a horizontal width of approximately 1 mm to approximately 3 mm or greater. As a final alternative, the region or zone may have a horizontal width of approximately 2 mm to approximately 6 mm or greater. The region or zone may be the far distance zone, the upper far-intermediate distance zone, the intermediate distance zone, the near distance zone, the lower far-intermediate distance zone, or any other region of the lens.

Image break: An image break is a perceived disruption in an image when looking through a lens. When an image break occurs, the image perceived through the lens is no longer seamless. An image break can be a prismatic displacement of the image across the image break, a magnification change of the image across the image break, a sudden blurring of the image at or around the image break, or some combination of the three. One method of determining whether a lens has an image break is to place the lens a fixed distance over a set of vertical lines, horizontal lines, or a grid. FIGS. 1A-10B show different lenses having −1.25D far distance correction and +2.25D add power held 6″ from a laptop screen displaying either vertical lines or a grid photographed 19.5″ from the laptop screen. FIGS. 1A and 1B show a lens according to an embodiment of the present invention. FIGS. 2A and 2B show a lens according to another embodiment of the present invention. FIGS. 3A and 3B show a lens according to another embodiment of the present invention. FIGS. 4A and 4B show a lens according to another embodiment of the present invention. FIGS. 5A and 5B show a flat top poly lens. FIGS. 6A and 6B show an easy top lens with slab-off prism. FIGS. 7A and 7B show an easy top lens. FIGS. 8A and 8B show a blended bifocal lens. FIGS. 9A and 9B show a flat top trifocal lens. FIGS. 10A and 10B show an executive lens. FIGS. 11A and 11B show a Sola SmartSeg™ lens trademarked by Sola Optical having −2.25D far distance correction and +2.00D add power held 6″ from a laptop screen displaying either vertical lines or a grid photographed 19.5″ from the laptop screen. FIGS. 12A-13B show different lenses having −1.25D far distance correction and +2.25D add power held 6″ from a laptop screen displaying either vertical lines or a grid photographed 19.5″ from the laptop screen. FIGS. 12A and 12B show a Varilux Physio 360™ lens trademarked by Essilor. FIGS. 13A and 13B show a Sola Compact Ultra™ lens trademarked by Carl Zeiss Vision. The lenses shown in FIGS. 1A-11B are lenses which produce a perceived image break. The lenses shown in FIGS. 12A-13B are lenses which do not produce a perceived image break.

Incremental Add Power: An add power that is less than the total add power required for a user to see clearly at a near distance. A region having an incremental add power typically has a maximum add power that is less than the total add power required for a user to see clearly at a near distance. Two or more regions, each having an incremental add power, may be placed in optical communication with each other. Because the regions are in optical communication with each other, the individual incremental add powers may be additive to create a total combined incremental add power that is equal to the add power required for a user to see clearly at a near distance. The incremental add power of a region may be generated refractively or diffractively using a refractive optic or a diffractive optic, respectively. In some cases, a region may have less than the total add power required for a user to see clearly at an intermediate distance. In such a case, the region is said to have an “incremental intermediate distance add power”.

Intermediate Distance Zone: The portion or region of a lens containing an optical power which allows a user to see clearly at an intermediate distance. The intermediate distance zone may also be referred to as the intermediate vision zone.

Intermediate Distance: The distance to which one looks, by way of example only, when reading a newspaper, when working on a computer, when washing dishes in a sink, or when ironing clothing. This distance is usually, but not always, considered to be between approximately 16 inches and approximately 29 inches from the eye. The intermediate distance may also be referred to as an intermediate viewing distance and an intermediate distance point. It should be pointed out that “intermediate distance” can also be referred to as “near-intermediate distance” since “near distance” is between approximately 10 inches to approximately 16 inches from the eye. Alternatively, only a portion of the “intermediate distance” which is closest to approximately 16 inches may be referred to as a “near-intermediate distance”. “Far-intermediate distance” is not to be confused with “intermediate distance”. “Far-intermediate distance” is instead between approximately 29 inches to approximately 5 feet (or 10 feet) from the eye.

Lens: Any device or portion of a device that causes light to converge or diverge. A lens may be refractive or diffractive. A lens may be either concave, convex, or piano on one or both surfaces. A lens may be spherical, cylindrical, prismatic, or a combination thereof. A lens may be made of optical glass, plastic, thermoplastic resins, thermoset resins, a composite of glass and resin, or a composite of different optical grade resins or plastics. A lens may be referred to as an optical element, optical preform, optical wafer, finished lens blank, or optic. It should be pointed out that within the optical industry a device can be referred to as a lens even if it has zero optical power (known as piano or no optical power). A lens is normally oriented as a person would wear the lens, such that the far distance zone of the lens is at the top and the near distance portion is at the bottom. The terms “upper”, “lower”, “above”, “below”, “vertical”, “horizontal”, “up”, “down”, “left”, “right”, “top”, and “bottom” when used in reference to a lens may be taken with respect to this orientation.

Lens Blank: A device made of optical material that may be shaped into a lens. A lens blank may be “finished” meaning that the lens blank has both of its external surfaces shaped into refractive external surfaces. A finished lens blank has an optical power which may be any optical power including zero or piano optical power. A lens blank may be a “semi-finished” lens blank, meaning that the lens blank has been shaped to have only one finished refractive external surface. A lens blank may be an “unfinished” lens blank, meaning that neither external surface of the lens blank has been shaped into a refractive surface. An unfinished surface of an unfinished or semi-finished lens blank may be finished by means of a fabrication process known as free-forming or by more traditional surfacing and polishing. A finished lens blank has not had its peripheral edge shaped, edged, or modified to fit into an eyeglass frame. For the purposes of this definition a finished lens blank is a lens. However, once a lens blank is shaped, edged, or modified to fit an eyeglass frame it is no longer referred to as a lens blank.

Lined Multifocal Lens: A multifocal lens that has two or more adjacent regions of different optical power having a visible discontinuity that can be seen by someone looking at a wearer of the lens. The discontinuity causes a perceived image break between the two or more regions. Examples of a lined multifocal lens are lined (non-blended) bifocals or trifocals.

Lineless Multifocal Lens: A multifocal lens that has two or more adjacent regions of different optical power having either no discontinuity between the two or more regions such as in a progressive addition lens or an invisible discontinuity between the two or more regions which can not be seen by someone looking at a wearer of the lens. The discontinuity causes a perceived image break between the two or more regions. An example of a lineless multifocal lens having a discontinuity is a blended bifocal. A PAL can also be referred to as a lineless multifocal, but a PAL does not have a discontinuity.

Low Add Power PAL: A Progressive Addition Lens that has less than the necessary near add power for the wearer to see clearly at a near viewing distance (i.e., it has an incremental add power).

Low Add Power Progressive Optical Power Region: A progressive optical power region that has less than the necessary near add power for the wearer to see clearly at a near viewing distance (i.e., it has an incremental add power).

Multifocal Lens: A lens having more than one focal point or optical power. Such lenses may be static or dynamic. Examples of static multifocal lenses include a bifocal lens, a trifocal lens or a Progressive Addition Lens. Dynamic multifocal lenses include, by way of example only, electro-active lenses. Various optical powers may be created in the electro-active lens depending on the types of electrodes used, voltages applied to the electrodes, and index of refraction altered within a thin layer of liquid crystal. Dynamic multifocal lenses also include, by way of example only, lenses comprising a conformable optical member such as gas lenses and fluid lenses, mechanically adjustable lenses where two or more movable members adjust the optical power, or electrical meniscus lenses. Multifocal lenses may also be a combination of static and dynamic. For example, an electro-active element may be used in optical communication with a static spherical lens, a static single vision lens, a static multifocal lens such as, by way of example only, a Progressive Addition Lens, a flat top 28 bifocal, or a flat top 7×28 trifocal. In most, but not all, cases, multifocal lenses are refractive lenses. In certain cases, a multifocal lens may comprise diffractive optics and/or a combination of diffractive and refractive optics.

Near Distance Zone: The portion or region of a lens containing an optical power which allows a user to see clearly at a near distance. The near distance zone may also be referred to as the near vision zone.

Near Distance: The distance to which one looks, by way of example only, when reading a book, when threading a needle, or when reading instructions on a pill bottle. This distance is usually, but not always, considered to be between approximately 10 inches and approximately 16 inches from the eye. The near distance may also be referred to as a near viewing distance or a near distance point.

Office Lens/Office PAL: A specially designed occupational Progressive Addition Lens that replaces the far distance vision zone with that of a mostly intermediate distance vision zone and typically provides near distance vision in a near distance zone and intermediate distance vision in an intermediate distance zone. The optical power degresses from the near distance zone to the intermediate distance zone. The total optical power degression is less optical power change than the wearer's typical near distance add power. As a result, wider intermediate distance vision is provided by a wider channel width and also a wider reading width. This is accomplished by means of an optical design which typically allows greater values of unwanted astigmatism above the fitting cross. Because of these features, this type of PAL is well-suited for desk work, but one cannot drive his or her car or use it for walking around the office or home since the lens contains little if any far distance viewing area.

Ophthalmic Lens: A lens suitable for vision correction which includes, by way of example only, a spectacle lens, a contact lens, an intra-ocular lens, a corneal in-lay, and a corneal on-lay.

Optical Communication: The condition whereby two or more optical power regions are aligned in a manner such that light passes through the aligned regions and experiences a combined optical power equal to the sum of the optical power of each individual region at the points through which the light passes. The regions may be embedded within a lens or on opposite surfaces of the same lens or different lenses.

Optical Power Region: A region of a lens having an optical power.

Plateau of Optical Power: A region or zone of a lens that has mostly constant optical power across the horizontal width and/or vertical length of the region or zone. Alternatively, the optical power change may be an average of approximately 0.05D per millimeter or less across the horizontal width and/or vertical length of the region or zone. As another alternative, the optical power change may be an average of approximately 0.10D per millimeter or less across the horizontal width and/or vertical length of the region or zone. As a final alternative, the optical power change may be an average of approximately 0.20D per millimeter or less across the horizontal width and/or vertical length of the region or zone. The region or zone may have a horizontal width and/or vertical length of approximately 1 mm or greater. As an alternative, the region or zone may have a horizontal width and/or vertical length of approximately 1 mm to approximately 3 mm or greater. As a final alternative, the region or zone may have a horizontal width and/or vertical length of approximately 2 mm to approximately 6 mm or greater. A plateau of optical power allows for vertical stability of optical power and/or horizontal stability of optical power within the region. A plateau of optical power would be recognized visually by a wearer of a lens by moving his or her chin up and down or by looking left and right. If a region has a plateau of optical power the wearer will notice that an object at a given distance stays mostly in focus throughout the region. The region or zone may be the far distance zone, the upper far-intermediate distance zone, the intermediate distance zone, the near distance zone, the lower far-intermediate distance zone, or any other region of the lens.

Progressive Addition Region: A continuous region of a PAL that contributes a continuous, increasing optical power between the far distance zone of the PAL and the near distance zone of the PAL. The add power in the far distance zone at the start of the region is approximately +0.10D or less. In some cases, the region may contribute a decreasing optical power after the full add power is reached in the near distance zone of the lens.

Progressive Addition Surface: A continuous surface of a PAL that contributes a continuous, increasing optical power between the far distance zone of the PAL and the near distance zone of the PAL. The add power in the far distance zone at the start of the surface is approximately +0.10D or less. In some cases, the surface may contribute a decreasing optical power after the full add power is reached in the near distance zone of the lens.

Progressive Optical Power Region: A region of a lens having a first optical power, typically in an upper portion of the region and a second optical power, typically in a lower portion of the region wherein a continuous change in optical power exists therebetween. A progressive optical power region may be on a surface of a lens or embedded within a lens. A progressive optical power region may comprise one or more surface topographies known as a “progressive optical power surface”. A progressive optical power surface may be on either surface of a lens or buried within the lens. A progressive optical power region is said to “begin” or “start” when the optical power is increased above the adjacent vision zone's optical power. Typically, this increase is a plus optical power of +0.12D or greater. The increased plus optical power at the start of the progressive optical power region may be caused by a mostly continuous increase in positive optical power. Alternatively, the add power at the start of the progressive optical power region may be caused by a step in optical power which is either part of the progressive optical power region or part of a different optical power region. The step in optical power may be caused by a discontinuity. The optical power of the progressive optical power region may decrease after reaching its maximum add power. A progressive optical power region may begin at or near the fitting point as in a conventional Progressive Addition Lens or may begin below the fitting point as in embodiments of the present invention.

Reading Width: The narrowest horizontal width within the near distance viewing portion of the lens which provides clear, mostly distortion free correction with an optical power within 0.25D of the wearer's near distance viewing optical power correction.

Short Channel Length: Due to aesthetic concerns or trends in eyewear fashion, it may be desirable to have a lens that is foreshortened vertically for fitting into a frame style which has a narrow, vertical height. In such a lens the channel is naturally also shorter. Short channel length refers to the length of a channel in a foreshortened lens. These channel lengths are usually, but not always between approximately 9 mm and approximately 13 mm. Generally, a shorter channel length means a narrower channel width and more unwanted astigmatism. Shorter channel designs are sometimes referred to as having certain characteristics associated with “hard” Progressive Addition Lens designs, since the transition between far distance correction and near distance correction is harder due to the steeper increase in optical power caused by the shorter vertical channel length.

Soft Progressive Addition Lens: A Progressive Addition Lens with a more gradual transition between the far distance correction and the near distance correction. This more gradual transition causes an increased amount of unwanted astigmatism. In a soft PAL the increased amount of unwanted astigmatism may intrude above an imaginary horizontal line located through the fitting point that extends across the lens. A soft PAL may also have a longer channel length and a wider channel width. A “modified soft Progressive Addition Lens” is a soft PAL which has a modified optical design having one or more of characteristics of a hard PAL such as: a steeper optical power transition, a shorter channel, a narrower channel, more unwanted astigmatism pushed into the viewing portion of the lens, and more unwanted astigmatism below the fitting point.

Static Lens: A lens having an optical power which is not alterable with the application of electrical energy, mechanical energy, or force. Examples of static lenses include spherical lenses, cylindrical lenses, Progressive Addition Lenses, bifocals, and trifocals. A static lens may also be referred to as a fixed lens.

Step in Optical Power: An optical power difference between two optical zones or regions that may result in an optical power discontinuity. The optical power difference may be a step up in optical power in which optical power increases between an upper portion and a lower portion of a lens. The optical power difference may be a step down in optical power in which optical power decreases between an upper portion and a lower portion of a lens. For example, if an upper portion of a lens has an optical power of +1.00D, a “step up” in optical power of +0.50D will result in a lower portion of the lens immediately after the step up in optical power (or discontinuity) having an optical power of +1.50D. The optical power in the lower region is said to be “created” by the step in optical power.

Unwanted Astigmatism: Unwanted astigmatism found within a lens that is not part of the patient's prescribed vision correction, but rather is a byproduct of the optical design of the lens due to the smooth gradient of optical power that joins two optical power zones. Although, a lens may have varying unwanted astigmatism across different areas of the lens of various dioptric powers, the term “unwanted astigmatism” generally refers to the maximum unwanted astigmatism that is found in the lens. Unwanted astigmatism may also be further characterized as the unwanted astigmatism located within a specific portion of a lens as opposed to the lens as a whole. In such a case qualifying language is used to indicate that only the unwanted astigmatism within the specific portion of the lens is being considered. The wearer of the lens will perceive unwanted astigmatism as blur and/or distortion caused by the lens. It is well known and accepted within the optical industry that as long as the unwanted astigmatism and distortion of a lens is approximately 1.00D or less, the user of the lens, in most cases, will barely notice it.

Vertical Stability of Optical Power: A region or zone of a lens that has mostly constant optical power across the vertical length of the region or zone. Alternatively, the optical power change may be an average of approximately 0.05D per millimeter or less across the vertical length of the region or zone. As another alternative, the optical power change may be an average of approximately 0.10D per millimeter or less across the vertical length of the region or zone. As a final alternative, the optical power change may be an average of approximately 0.20D per millimeter or less across the vertical length of the region or zone. The region or zone may have a vertical length of approximately 1 mm or greater. As an alternative, the region or zone may have a vertical length of approximately 1 mm to approximately 3 mm or greater. As a final alternative, the region or zone may have a vertical length of approximately 2 mm to approximately 6 mm or greater. The region or zone may be the far distance zone, the upper far-intermediate distance zone, the intermediate distance zone, the near distance zone, the lower far-intermediate distance zone, or any other region of the lens.

Vertical Stability of Vision: A region or zone of a lens is said to have vertical stability of vision if the region or zone has mostly constant clear vision as a user looks up and down across the region or zone. However, it should be pointed out that while a PAL has clear vision from the far distance zone to the near distance zone, the optical power between these zones is blended. Therefore, a PAL has blended stability of vision between the far distance and near distance zones. Thus, a PAL has a very limited vertical stability of optical power between the far distance zone and the near distance zone. The region or zone may have a vertical length of approximately 1 mm or greater. As an alternative, the region or zone may have a vertical length of approximately 1 mm to approximately 3 mm or greater. As a final alternative, the region or zone may have a vertical length of approximately 2 mm to approximately 6 mm or greater. The region or zone may be the far distance zone, the upper far-intermediate distance zone, the intermediate distance zone, the near distance zone, the lower far-intermediate distance zone, or any other region of the lens.

Embodiments of the present invention relate to an optical design, lens, and eyewear system that may solve many, if not most, of the problems associated with PALs. In addition, the embodiments may significantly remove most of the vision compromises associated with PALs. The embodiments may provide a means of achieving the proper far distance, intermediate distance, and near distance optical powers for the wearer while providing mostly continuous focusing ability for various distances. The embodiments may also provide a means of achieving the proper upper far-intermediate distance and/or lower far-intermediate distance optical powers for the wearer while providing mostly continuous focusing ability. The embodiments may have far less unwanted astigmatism than a PAL. The embodiments may allow for a full range of presbyopic correction with add powers from +1.00D to +3.50D in either +0.12D steps or +0.25D steps. For add power prescriptions below +3.00D, the embodiments typically keep the unwanted astigmatism to a maximum of approximately 1.00D or less. For certain high add power prescriptions such as +3.00D, +3.25D, and +3.50D, the embodiments typically keep the unwanted astigmatism to a maximum of approximately 1.50D.

Embodiments of the present invention may allow for optically combining two discrete optical elements into one multifocal lens. The first optical element may have a mostly spherical power region that contributes a mostly spherical optical power. The mostly spherical optical power may be generated refractively or diffractively by a refractive optic or a diffractive optic, respectively. The second optical element may have a progressive optical power region that contributes a progressive optical power. The second optical element contributing progressive optical power may not provide enough add power for the user to see clearly at a near distance (i.e., the second optical element has an incremental add power). The first optical element may contribute a mostly spherical optical power that provides an optical power in addition to that provided by the second optical element to allow the user to see clearly at a near distance (i.e., the first optical element has an incremental add power that when combined with the second optical element's incremental add power totals the user's near distance add power). Because a portion of the total add power is provided by the first optical element contributing mostly spherical optical power, the multifocal lens may have less unwanted astigmatism than a PAL having the same total add power.

In an embodiment of the present invention, the first optical element may be a buried diffractive optic having a different index of refraction than the surrounding material of the lens. In another embodiment, the first optical element may be a buried refractive optic having a different index of refraction than the surrounding material of the lens. In another embodiment, the first optical element may be a buried electro-active element. In another embodiment, the first optical element may be on one or both surfaces of the lens and may be provided, for example, by grinding, molding, surface casting, stamping, or free forming an outer surface of the lens.

In an embodiment of the present invention, the second optical element may be on one or both surfaces of the lens and may be provided, for example, by grinding, molding, surface casting, stamping, or free forming an outer surface of the lens. In another embodiment, the second optical element may be buried within the lens and have a gradient of indices of refraction different than the surrounding material of the lens. Typically, but not always, if one of the optical elements is buried within the lens, the other optical element is located on one or both outer surfaces of the lens.

In an embodiment of the present invention, the first optical element contributing mostly spherical optical power is in optical communication with at least a portion of the second optical element contributing progressive optical power. In another embodiment, the first optical element contributing mostly spherical optical power and the second optical element contributing progressive optical power are mathematically combined into a single optical element which may be on an outer refractive surface of the lens or buried within the lens.

Embodiments of the present invention provide for the proper alignment and positioning of the first optical element contributing mostly spherical optical power and the second optical element contributing progressive optical power. Embodiments of the present invention also provide for the amount of optical power provided by the mostly spherical power region, the amount of optical power provided by the progressive optical power region, and the optical design of the progressive optical power region. Embodiments of the present invention also provide for the size and shape of the mostly spherical power region and the size and shape of the progressive optical power region. The combination of these design parameters allows for a far superior optical design which has less unwanted astigmatism and distortion as well as both a wider channel width and a shorter channel length compared to state of the art PALs commercially available today.

It should be pointed out that the figures, and any features shown in the figures, are not drawn to scale. FIG. 14A shows a view of the front surface of a lens according to an embodiment of the present invention. FIG. 14B shows a view of the front surface of a different embodiment of the present invention. FIGS. 14A-14B show that the front convex surface of the lens has two optical power regions. The first optical power region is a far distance zone 1410 in the upper portion of the lens. The second optical power region is a mostly spherical power region 1420 in the lower portion of the lens that contributes an additive optical power. The additive optical power may be an incremental add power. In FIG. 14A, the mostly spherical power region is in the shape of an arched section of the lens. The arched section may be thought of as a circular region having a diameter much larger than the diameter of the lens. Because the circular region is too large for the lens, only the top arch of its perimeter fits within the lens. In FIG. 14B, the mostly spherical power region is a circular shape. The mostly spherical power region is located below a fitting point 1430. Alternatively, the mostly spherical power region may be located at or above the fitting point. A discontinuity in optical power exists between the far distance zone and the mostly spherical power region. At least a portion of the discontinuity may be blended by a blend zone 1440 located between the two optical power regions. The blend zone may be approximately 2.0 mm wide or less or approximately 0.5 mm wide or less. FIG. 14C shows a view of the back surface of the lens of either FIG. 14A or FIG. 14B according to an embodiment of the present invention. FIG. 14C shows that the back concave surface of the lens has a progressive optical power region 1450 that contributes an additive optical power. The additive optical power may be an incremental add power. It should be pointed out that when the progressive optical power region is found on the back concave surface of the lens in most, but not in all, cases the back concave surface also comprises toric curves to correct for the patient's astigmatic refractive error. The progressive optical power region starts below the fitting point of the lens. Alternatively, FIG. 14D shows a view of the back surface of the lens of either FIG. 14A or FIG. 14B according to an embodiment of the present invention in which the progressive optical power region starts at or near the fitting point of the lens. When the progressive optical power region starts at the upper edge of the mostly spherical power region, as in FIG. 14D, a step in optical power 1470 is provided that is additive to the optical power provided at the start of the progressive optical power. When the progressive optical power region begins above the mostly spherical power region (not shown), the upper edge of the mostly spherical power region causes a discontinuity across the channel of the progressive optical power region.

FIG. 14E shows a cross-sectional view of the lens of FIGS. 14A and 14C taken through the center vertical line of the lens according to an embodiment of the present invention. As can be seen in FIG. 14E, a far distance optical power 1415 is provided in the far distance zone. The mostly spherical power region and the progressive optical power region are aligned to be in optical communication with each other such that the optical power contributed by each region combines in the near distance zone 1460 to provide a total near distance add power 1465 for the user. The progressive optical power region begins below the fitting point and ends at or above the bottom of the lens. FIG. 14F shows the inventive lens from the front showing the placement and optical alignment of the optical power regions of FIGS. 14A and 14C on the front and back surfaces of the lens according to an embodiment of the present invention. FIG. 14G shows the inventive lens from the front showing the placement and optical alignment of the optical power regions of FIGS. 14B and 14C on the front and back surfaces of the lens according to an embodiment of the present invention. As can be seen in both FIGS. 14F and 14G, the progressive optical power region starts at a portion of the mostly spherical power region and is spaced apart and below the discontinuity.

As mentioned above, in some embodiments of the present invention the mostly spherical power region, blend zone, and progressive optical power region may be mathematically combined and located on a single surface of the lens. In an example of such an embodiment, a wearer of the lens requires no correction for far distance and +2.25D for near distance correction. FIG. 15A illustrates a mostly spherical power region 1510 located in the bottom portion of a surface of a lens according to an embodiment of the present invention. The mostly spherical power region may generate optical power refractively. The lens has a blend zone 1520 which transitions between the optical power in the far distance zone and the optical power of the mostly spherical power region. By way of example only, in the lens of FIG. 15A, the mostly spherical power region has an optical power of +1.25D and the far distance zone has a plano optical power. Thus, the mostly spherical power region may have an incremental add power. FIG. 15B illustrates a progressive optical power region 1530 located on a surface of a lens according to an embodiment of the present invention. As has been pointed out this could be on the front convex surface, the back concave surface, or on both the front convex surface and the back concave surface. By way of example only, in the lens of FIG. 15B, the progressive optical power region has an add power of +1.00D. Thus, the progressive optical power region may have an incremental add power. FIG. 15C illustrates a single surface of a lens which is a combination of the surface of the lens shown in FIG. 15A and the surface of the lens shown in FIG. 15B according to an embodiment of the present invention. By way of example only, in the lens of FIG. 15C, the near distance zone optical power is +2.25D which is a combination of the +1.25D of optical power contributed by the mostly spherical power region and the +1.00D of optical power contributed by the progressive optical power region. It should be noted that in FIG. 15C the progressive optical power region is optically aligned to start at a portion of the mostly spherical power region and is spaced apart and below the blend zone.

In some embodiments of the present invention the two surfaces may be combined by adding the geometries of the two surfaces together mathematically thereby creating a new single surface. This new single surface may then be fabricated from a mold that may be produced by free-forming or by diamond-turning. The mold can be used to produce semi-finished lens blanks that can be surfaced by any optical laboratory.

By describing each of the two surfaces in terms of a geometric function in Cartesian coordinates, the surface in FIG. 15A can be mathematically combined with the surface described in FIG. 15B to create the new surface shown in FIG. 15C, which is a combination of the two surfaces.

The surface that defines or produces the mostly spherical power region and blend zone may be divided into discrete equally sized sections. Each section may be described as a localized height or a localized curve relative to a fixed surface or fixed curvature, respectively. Such a surface can be described with the following equation:

${Z_{1}\left( {x,y} \right)} = {\sum\limits_{i = 0}^{n_{1}}{\sum\limits_{j = 0}^{n_{2}}{S\left( {x_{i},y_{j}} \right)}}}$

Similarly the surface that defines or produces the progressive optical power region may be divided into discrete equally sized sections that are the same size as the above mentioned sections. Each section may be described as a localized height or a localized curve relative to a fixed surface or fixed curvature, respectively. Such a surface can be described with the following equation:

${Z_{2}\left( {x,y} \right)} = {\sum\limits_{i = 0}^{n_{1}}{\sum\limits_{j = 0}^{n_{2}}{P\left( {x_{i},y_{j}} \right)}}}$

If the sections of the two surfaces are the same size, combining sections from each surface is straightforward. The combined surface may then be described by the simple superposition of the two surfaces or:

Z ₃(x,y)=Z ₁(x,y)+Z ₂(x,y)

This process is illustrated in FIG. 15D according to an embodiment of the present invention.

The size of the sections should be as small as possible to achieve an accurate representation of each surface. Further optimization of the progressive optical power region may be done after the two surfaces are combined, or the progressive optical power region can be pre-optimized for better combination with the mostly spherical power region and blend zone. If desired, the blend zone may not be combined and only the mostly spherical power region and progressive optical power region are combined.

The two surfaces may also be combined by the methods described is U.S. Pat. No. 6,883,916 to Menezes and U.S. Pat. No. 6,955,433 to Wooley, et al., both of which are hereby incorporated by reference in their entirety.

The inventors have discovered the importance of a range of distances that has heretofore never been corrected in the same manner in the ophthalmic arts. The range of distances lies between approximately 29 inches and approximately 5 feet and has been found to be particularly important for tasks such as focusing to the far edge of one's desk. In the prior art, this range of distances has been largely overlooked and has been lumped together in prior art definitions with the category of either far distance or intermediate distance. Therefore, this range of distances has been corrected as part of one of these categories. The inventors refer to this range of distances as a “far-intermediate distance”. A new vision zone termed a “far-intermediate distance zone” has been invented to provide for proper focusing ability for this inventive far-intermediate distance. Embodiments of the present invention may include this far-intermediate distance zone and may optimize the optical power in this zone to provide proper focusing ability for a far-intermediate distance. Embodiments of the present invention may include this far-intermediate distance zone and may optimize the location of this zone in the lens to provide for proper ergonomic use of the lens. When this zone is located between the far distance zone and the intermediate distance zone it is termed an “upper far-intermediate distance zone”. When this zone is located below the near distance zone it is termed a “lower far-intermediate distance zone”.

Typically, prior art multifocal lenses do not provide for proper focusing ability at a far-intermediate distance or provide for only limited focusing ability at a far-intermediate distance. For example, the far distance region or zone of bifocals is prescribed for an individual wearer to allow for focusing ability at a far viewing distance such as optical infinity which is approximately 20 feet or greater. However, it should be noted that in most cases the same far distance optical power will suffice for the wearer when viewing distances of approximately 5 feet or greater. The near distance region or zone of bifocals is prescribed to allow for focusing ability at a near viewing distance of approximately 10 inches to approximately 16 inches. Trifocals allow for proper focusing ability at a far viewing distance, a near viewing distance, and at an intermediate viewing distance (from approximately 16 inches to approximately 29 inches). PALs provide clear continuous vision between a far viewing distance and a near viewing distance. However, because the optical power in a PAL continuously transitions from the far distance zone to the near distance zone, the vertical stability in this transition zone of the PAL is very limited.

Unlike a PAL, embodiments of the present invention may provide for vertical stability in a particular zone or zones of the lens. Vertical stability in a zone may be provided by a step in optical power that may cause a discontinuity. In addition, embodiments of the present invention may provide for a location of the step or steps that is least distracting to a wearer's vision. Also, embodiments of the present invention may provide for forming the step or steps so they are mostly invisible when one looks at the face of a wearer of the lens. Embodiments of the present invention may also provide for forming the step or steps so the wearer's eyes can comfortably translate over the step or steps when looking from zone to zone such as, for example, when looking from the far distance zone to the near distance zone. Finally, in certain embodiments of the present invention the lens may provide for continuous uninterrupted focusing ability between approximately 4 to 5 feet and approximately 10 inches to 12 inches from the eye of the wearer with only a single discontinuity which is comfortably transitioned over when the wearer focuses between a far distance object and an object at or less than 4 to 5 feet from the wearer's eye. In still other embodiments of the present invention the step in optical power may occur between the far distance zone and the intermediate distance zone whereby the lens allows for continuous uninterrupted focusing ability between approximately 29 inches and approximately 10 inches to 12 inches from the eye of the wearer with only a single discontinuity which is comfortably transitioned over when the wearer focuses between a far distance object and an object at or less than approximately 29 inches from the wearer's eye.

In embodiments of the present invention it may be necessary to align the mostly spherical power region and the progressive optical power region to ensure that the correct total optical power is provided in the far-intermediate zone and in the intermediate distance zone. The far-intermediate distance zone typically has an add power between approximately 20% and approximately 44% of the near distance add power. The intermediate distance zone typically has an add power between approximately 45% and approximately 55% of the near distance add power. It may also be necessary to align and position these regions to create a usable and ergonomically feasible lens for when the wearer's line of sight transitions between the various zones (far distance zone, far-intermediate distance zone, intermediate distance zone, and near distance zone). Lastly, it may also be necessary to design the gradient of optical power that exists between the far distance vision correction and the near distance vision correction to ensure an optimal intermediate distance correction and/or far-intermediate distance correction.

In an embodiment of the present invention, the mostly spherical power region may be located between approximately 0 mm and approximately 7 mm below the fitting point. In another embodiment of the present invention, the mostly spherical power region may be located between approximately 2 mm and approximately 5 mm below the fitting point. In an embodiment of the present invention, the progressive optical power region may start at a portion of the mostly spherical power region approximately 2 mm to approximately 10 mm below the top edge of the mostly spherical power region. In another embodiment of the present invention, the progressive optical power region may start at a portion of the mostly spherical power region approximately 4 mm to approximately 8 mm below the top edge of the mostly spherical power region. In an embodiment of the present invention, the far-intermediate distance power may start between approximately 3 mm and approximately 4 mm below the fitting point and extend for approximately 4 mm down the channel. In an embodiment of the present invention, the intermediate distance power may start after the far-intermediate distance zone and extend for approximately 3 mm to approximately 4 mm down the channel. The aforementioned measurements are exemplary only, and are not intended to limit the present invention.

If the mostly spherical power region and progressive optical power region are not aligned and positioned properly, the user of the lens will not have proper vision correction in usable portions of the lens. For example, if the mostly spherical power region is located much above the fitting point, the wearer may have too much optical power for far distance viewing when looking straight ahead. As another example, if the low add power progressive optical power region is located too high in the lens, the combined optical power in the intermediate distance zone provided by the mostly spherical power region and the progressive optical power region may be too high for the wearer.

FIG. 16 and FIG. 17 show three conventional PAL designs (the Essilor Physio™ lens trademarked by Essilor, the Essilor Ellipse™ lens trademarked by Essilor, and the Shamir Piccolo™ lens trademarked by Shamir Optical) having a near distance add power of +1.25D according to embodiments of the present invention. FIG. 16 shows an add power gradient for the three lenses as measured by a Rotlex Class Plus™ trademarked by Rotlex. FIG. 17 shows measurements taken every 3 mm from the fitting point down the channel of the add power in the three lenses as measured by a Rotlex Class Plus™.

FIG. 18 shows measurements taken every 3 mm from the fitting point down the channel of the add power in three embodiments of the present invention. In these embodiments, the three lenses of FIG. 16 and FIG. 17 are placed in optical communication with a mostly spherical power region having an optical power of +1.00D. In these embodiments, the progressive optical power region starts at the fitting point and the top edge of the mostly spherical power region is placed just below the fitting point. As can be seen from FIG. 18, the add power of the lenses at 9 mm below the fitting point is too strong. The region of the lens 9 mm below the fitting point would typically be part of the intermediate distance zone. For a +2.25D near distance add power the intermediate distance add power should be +1.12D. However, the Essilor Physio™ embodiment has +1.63D add power at 9 mm from the fitting point, the Essilor Ellipse™ embodiment has +1.82D add power at 9 mm from the fitting point, and the Shamir Piccolo™ embodiment has +1.68D add power at 9 mm from the fitting point. Because there is too much add power in the intermediate distance zone, a user of the lens may feel as if his or her eyes are pulling or crossing. This may cause headaches and the user will have to hold objects closer to his or her eyes to focus properly through this zone. Thus, if the optical power, placement, and alignment of the mostly spherical power region and progressive optical power region are not optimized, the resulting lens will have one or more of the following: poor vision ergonomics, poor vision comfort, and poor vision clarity.

As another example, FIG. 19 shows an add power gradient for both an embodiment of the present invention on the left and an Essilor Physio™ lens on the right as measured by a Rotlex Class Plus™. Both the embodiment and the Physio™ lens have an add power of +2.25D. The embodiment has a mostly spherical power region having an optical power of +1.25D and a progressive optical power region having an add power of +1.00D. The top of the progressive optical power region starts just below the fitting point and the top of the mostly spherical power region is located 4 mm below the fitting point. Thus, there is a region of the lens where only the progressive optical power region contributes increasing optical power before the mostly spherical power region begins to add optical power to the lens. FIG. 20 shows measurements taken every 3 mm from the fitting point down the channel of the add power in the two lenses of FIG. 19 as measured by a Rotlex Class Plus™. This embodiment of the present invention has an add power of +1.60D at 9 mm from the fitting point compared to that of the Essilor Physio™ which has an add power of +1.10D at 9 mm from the fitting point. As before, if the optical power, placement, and alignment of the mostly spherical power region and progressive optical power region are not optimized, the resulting lens will have poor vision ergonomics, poor vision comfort, and poor vision clarity. This is true even when the correct full add power is provided by the lens as it is at 15 mm below the fitting point in FIGS. 18 and 20.

Therefore, even though these embodiments of the present invention have numerous superior attributes (such as less unwanted astigmatism) compared to state-of-the-art PALs, it should be obvious that such lenses would be rejected by a user. The embodiments of the present invention have too much add power in the intermediate distance zone and the optical power gradient from the fitting point to the bottom of the lens is too steep.

By comparing the add power measurements shown in FIG. 18 and FIG. 20 for the Essilor Physio™ lens, it should be apparent that one cannot add a +1.00D spherical power region to the Essilor Physio™ lens of FIG. 17 and thereby approximate the Essilor Physio™ lens of FIG. 20. It should therefore be apparent that the mostly spherical power region and/or the progressive optical power region must be specifically designed to take into account the gradient of optical power between the far distance zone and near distance zone to provide for a proper intermediate distance correction and/or far-intermediate distance correction.

FIG. 21 shows four regions of a lens: a far distance zone 2110, an upper far-intermediate distance zone 2120, an intermediate distance zone 2130, and a near distance zone 2140 according to embodiments of the present invention. These regions are not shown to scale. The upper far-intermediate distance zone may have a height from point H to point I and a width from point A to point B. The intermediate distance zone may have a height from point I to point J and a width from point C to point D. The near distance zone may have a height from point J to point G and a width from point E to point F. In certain embodiments of the present invention the inventive lens may provide proper correction for a wearer for the far distance zone and the near distance zone and provide an optimized gradient of optical power allowing the wearer to see properly at a far-intermediate distance and an intermediate distance. In certain embodiments of the present invention, the lens may have vertical stability of vision in the upper far-intermediate distance zone and/or vertical stability of vision in the intermediate zone. In embodiments of the present invention that do not have a far-intermediate zone, the intermediate distance zone may have increased vertical stability of vision (i.e., extend further vertically).

An additional far-intermediate distance region may be provided below the near distance zone. In such an embodiment, this region may be referred to as the “lower” far-intermediate distance zone and the far-intermediate distance region between the far distance region and the intermediate distance region may be referred to as the “upper” far-intermediate distance region. The upper and lower far-intermediate zones may have the same optical power. The lower far-intermediate zone may be included in embodiments of the present invention to allow the presbyopic wearer to see his or her feet or the floor more easily when looking downwards. This may provide additional safety when walking up and down stairs.

Embodiments of the present invention may include one or more discontinuities between regions of the lens. Typically, embodiments of the present invention only include a single discontinuity. The discontinuities, may be caused by a discontinuous surface or by discontinuous optical power between two different regions of the lens. The discontinuities may be caused by a step up or a step down in optical power. A discontinuity is defined by any change in a surface of a lens or in an optical power of the lens that results in a perceived image break when looking through the lens. By way of example only, the inventors have fabricated a variety of lenses and have found that it is difficult to perceive an image break when a lens has an optical power discontinuity of less than approximately 0.10D when the lens is positioned at a distance from the eye consistent with how spectacle lenses are typically worn. However, optical power discontinuities larger than approximately 0.10D to 0.12D can be visually detected by a wearer in most cases. Furthermore, such optical power discontinuities that can be perceived by a wearer of the lens can be disturbing to the wearer's vision during certain visual tasks such as, for example, viewing a computer screen. It should be noted that the optical power values stated above for a discontinuity are only exemplary and a discontinuity is defined as any change in a surface or optical power of a lens that results in the ability to perceive an image break when looking through the lens.

The inventors have further established that certain discontinuities are more noticeable and/or disturbing than others. Embodiments of the present invention may therefore include one or more discontinuities that are less noticeable and/or less disturbing. The inventors have found that a discontinuity between the far distance zone and the upper far-intermediate distance zone of the lens is visually tolerated by a user far better than a discontinuity located within the intermediate distance zone, the near distance zone, or between the intermediate distance zone and the near distance zone. In addition, the inventors have established that the narrower the width of a blend zone which blends at least a portion of the discontinuity, the better the eye transitions over the discontinuity due to the fact that the eye transitions more quickly over any image break or blur created by the blend zone. Although this would seem to indicate that the discontinuity should therefore not be blended, this must be balanced by the positive cosmetic effect of blending the discontinuity to create a nearly invisible discontinuity.

Embodiments of the present invention may comprise one or more discontinuities, wherein a discontinuity may be caused by a step up in optical power of +0.12D or more. Embodiments may have a single discontinuity which is at least partially blended by a blend zone having a width less than approximately 2.0 mm or between approximately 1.0 mm and 0.5 mm. Blend zones of this width can be generated by diamond turning. However, in other embodiments of the present invention the discontinuity is not blended. In embodiments of the present invention the discontinuity may be created by a step up in optical power of over approximately +0.25D and in most cases over approximately +0.50D. The step up in optical power and thus the discontinuity is usually, but not always, located between the far distance zone of the inventive lens and the far-intermediate distance zone. Alternatively, when the lens does not have a far-intermediate distance zone, the discontinuity is usually located between the far distance zone and the intermediate distance zone of the lens. FIGS. 25 and 26 show such a step up in optical power prior to the start of the progressive optical power region according to embodiments of the present invention.

All embodiments of the present invention allow for the ability to have three usable zones of optical power: a far distance zone, an intermediate distance zone, and a near distance zone. Embodiments of the present invention may also provide for the ability to have a fourth zone, an upper far-intermediate distance zone and, in some embodiments, a fifth zone, a lower far-intermediate distance zone. Embodiments of the present invention may:

-   -   a) Increase the length of the channel to allow for an additional         2 mm to 3 mm plateau of optical power to provide for upper         far-intermediate distance correction. Such an optical power zone         may be useful when using one's computer or looking to the edge         of one's desk. It should be noted that increasing the channel         length may not be possible depending on the vertical dimensions         of the eyeglass frame which will house the lens.     -   b) Increase the length of the channel to allow for an additional         2 mm to 3 mm plateau of optical power to provide for lower         far-intermediate distance correction. Such an optical power zone         may be useful when looking at one's feet or the floor when         climbing up or down stairs. It should be noted that increasing         the channel length may not be possible depending on the vertical         dimensions of the eyeglass frame which will house the lens.     -   c) Utilize one or more discontinuities. The one or more         discontinuities may be caused by one or more steps in optical         power, wherein a step is either a step up or a step down in         optical power. Because a discontinuity uses very little, if any,         lens real estate to step up or down the optical power, the         channel can be designed to allow for a plateau of optical power         without extending the length of the channel. It is important to         note that the larger the step in optical power, the more real         estate in the lens can be provided for an optical power plateau.         In embodiments of the invention, a plateau of optical power may         be provided after a discontinuity and provides for a         far-intermediate distance correction. This is accomplished         without adding to the length of the channel. FIG. 22 shows an         embodiment of the present invention having two plateaus of         optical power; 2230 and 2240 and FIG. 23 shows an embodiment of         the present invention having three plateaus of optical power:         2330, 2340, and 2350.     -   d) Keep the length of the channel the same, but ramp up the         optical power more quickly between the various zones of optical         power. It should be noted that this usually results in problems         with vision comfort and eye fatigue of the wearer.     -   e) Use a step down in optical power immediately below the near         distance zone to allow for a lower far-intermediate distance         zone. It should be noted that a lower far-intermediate distance         zone may only be possible if there is enough lens real estate         below the near distance portion of the lens.

FIG. 22 shows the optical power along the center vertical mid-line of an embodiment of the present invention including a progressive optical power region connecting the far distance zone to the near distance zone. The figure is not drawn to scale. The optical power in the far distance zone is shown as piano and is therefore represented by the x-axis 2210. The progressive optical power region begins at the fitting point of the lens 2220. Alternatively, the progressive optical power region may begin below the fitting point. Although the optical power of the progressive optical power region increases over the length of the channel, the progressive optical power region may provide for two plateaus of optical power within the channel. The first plateau 2230 provides an upper far-intermediate distance correction and the second plateau 2240 provides an intermediate distance correction. Alternatively, the progressive optical power region provides for a single plateau of optical power which provides either an intermediate distance correction or a far-intermediate distance correction. The first plateau of optical power may have a vertical length along the channel between approximately 1 mm and approximately 6 mm or between approximately 2 mm and approximately 3 mm. However, in all cases, a plateau of optical power has a vertical length of at least approximately 1 mm. In cases with two plateaus, after the first plateau of optical power the optical power contributed by the progressive optical power region increases until a second plateau of optical power. The second plateau of optical power may have a vertical length along the channel between approximately 1 mm and approximately 6 mm or between approximately 2 mm and approximately 3 mm. After the second plateau of optical power the optical power contributed by the progressive addition region increases until the total near distance optical power is reached at 2250. After the near distance optical power is achieved the optical power contributed by the progressive optical power region may begin to decrease. If the optical power decreases to between approximately 20% to approximately 44% of the add power in the near distance zone, a lower far-intermediate zone may be provided.

FIG. 23 shows the optical power along the center vertical mid-line of an embodiment of the present invention including a progressive optical power region connecting the far distance zone to the near distance zone. The figure is not drawn to scale. The optical power in the far distance zone is shown as piano and is therefore represented by the x-axis 2310. The progressive optical power region begins at the fitting point of the lens 2320. Alternatively, the progressive optical power region may begin below the fitting point. Although the optical power of the progressive optical power region increases over the length of the channel, the progressive optical power region may provide for three plateaus of optical power within the channel. The first plateau 2330 provides an upper far-intermediate distance correction, the second plateau 2340 provides an intermediate distance correction, and the third plateau 2350 provides a near distance correction. The first plateau of optical power may have a vertical length along the channel between approximately 1 mm and approximately 6 mm or between approximately 2 mm and approximately 3 mm. However, in all cases, a plateau of optical power has a vertical length of at least approximately 1 mm. After the first plateau of optical power the optical power contributed by the progressive optical power region increases until a second plateau of optical power. The second plateau of optical power may have a vertical length along the channel between approximately 1 mm and approximately 6 mm or between approximately 2 mm and approximately 3 mm. After the second plateau of optical power the optical power contributed by the progressive optical power region increases until a third plateau of optical power. The third plateau of optical power may have a vertical length along the channel between approximately 1 mm and approximately 6 mm or between approximately 2 mm and approximately 3 mm. After the near distance optical power is achieved at 2360 the optical power contributed by the progressive optical power region may begin to decrease. If the optical power decreases to between approximately 20% to approximately 44% of the add power in the near distance zone, a lower far-intermediate zone may be provided.

FIG. 24 shows the optical power along the center vertical mid-line of an embodiment of the present invention including a mostly spherical power region, a discontinuity, and a progressive optical power region connecting the far distance zone to the near distance zone. The figure is not drawn to scale. The optical power in the far distance zone is shown as piano and is therefore represented by the x-axis 2410. The progressive optical power region begins at or near the fitting point of the lens 2420. The discontinuity 2430 may be caused by the mostly spherical power region, which causes a step in optical power, and contributes an optical power 2440. The progressive optical power region may start above the discontinuity. In this case, the start of the progressive optical power region may be located by measuring the optical power in the far distance zone and then locating an area or region of the lens above the discontinuity where the optical power of the lens begins to gradually increase in plus optical power or reduce in minus optical power. The difference between the optical power just before the discontinuity and just after the discontinuity is referred to as a “step in optical power”. A “step up in optical power” occurs if the optical power increases from before the discontinuity to after the discontinuity. A “step down in optical power” occurs if the optical power decreases from before the discontinuity to after the discontinuity. Thus, if the progressive optical power region starts above the discontinuity, immediately before the discontinuity the total optical power in the lens is the optical power of the progressive optical power region and the far distance zone and immediately after the discontinuity the total optical power in the lens is the optical power caused by the step in optical power and the optical power of the progressive addition region and the far distance zone. Alternatively, the progressive optical power region may start below the discontinuity such that immediately before the discontinuity the total optical power in the lens is the far distance optical power and after the discontinuity, once the progressive optical power region starts, the total optical power in the lens is the optical power caused by the step in optical power and the optical power of the progressive addition region and the far distance zone. The progressive optical power region may begin immediately after the discontinuity. Alternatively, the progressive optical power region may begin 1 or more millimeters from the discontinuity thereby creating a plateau of optical power 2450 that may be useful for intermediate distance viewing or upper far-intermediate distance viewing. In some embodiments of the present invention the progressive optical power region may have a negative optical power 2460 such that the region decreases the total optical power in the lens before having a positive optical power that increases the total optical power in the lens. For example, the optical power caused by the step in optical power may be higher than the optical power needed for proper far-intermediate distance viewing. In this case, a portion of the progressive optical power region at and immediately after the discontinuity may decrease the optical power of the lens to provide a proper upper far-intermediate distance correction. The progressive optical power region may then increase in optical power to provide a proper intermediate distance correction 2470. The optical power of the progressive optical power region may further increase until the full near distance optical power 2480 after which it may begin to decrease again. Thus, the mostly spherical power region and the progressive optical power region may each have an incremental add power which together provide the total add power of the lens. If the optical power decreases to between approximately 20% to approximately 44% of the add power in the near distance zone, a lower far-intermediate zone may be provided.

In embodiments of the present invention in which the progressive optical power region begins above the discontinuity, the optical power contributed by the progressive optical power region may initially be zero or negative. The discontinuity may be caused by a step in optical power. The optical power caused by the step in optical power may be approximately equal to the optical power needed for proper intermediate distance correction or for far-intermediate distance correction. Therefore, if the initial optical power contributed by the progressive optical power region is zero, the combined optical power after the discontinuity will be the proper intermediate distance correction or far-intermediate distance correction. Similarly, the optical power caused by the step in optical power may be larger than the optical power needed for proper intermediate distance correction or for far-intermediate distance correction. Therefore, if the initial optical power contributed by the progressive optical power region is negative, the combined optical power after the discontinuity will be the proper intermediate distance correction or far-intermediate distance correction. In either case, if the progressive optical power region initially contributed a positive optical power, the combined optical power after the discontinuity may be too strong. This was proven to be the case in FIGS. 16-20. Furthermore, it should be noted that if the step in optical power causes a higher optical power than needed for proper intermediate distance correction or for far-intermediate distance correction, a lower add power progressive optical power region may be used thereby improving the optical characteristics of the lens. It should be noted that the lower the progressive optical power region's optical power, the less unwanted astigmatism and distortion will be added to the final lens.

Alternatively, in embodiments of the present invention in which the progressive optical power region begins above the discontinuity, the optical power contributed by the progressive optical power region may initially be positive. In these embodiments, the optical power caused by the step in optical power is reduced to be less than the optical power needed for proper intermediate distance correction or for proper far-intermediate distance correction. Therefore, if the initial optical power contributed by the progressive optical power region is positive, the combined optical power after the discontinuity will be the proper intermediate distance correction or far-intermediate distance correction. However, it should be noted that in this embodiment the unwanted astigmatism and distortion are greater in the final lens than an embodiment in which the mostly spherical region's optical power is equal to or greater than the optical power contributed by the progressive optical power region.

FIG. 25 shows the optical power along the center vertical mid-line of an embodiment of the present invention including a mostly spherical power region, a discontinuity, and a progressive optical power region connecting the far distance zone to the near distance zone. The figure is not drawn to scale. The optical power in the far distance zone is shown as piano and is therefore represented by the x-axis 2510. The discontinuity 2520 may be located below the fitting point 2530, for example, approximately 3 mm below the fitting point. The discontinuity may be caused by the mostly spherical power region, which causes a step in optical power, and contributes an optical power 2540. The progressive optical power region may start at a portion of the mostly spherical power region, for example, immediately after the discontinuity or shortly thereafter at 2550. The mostly spherical power region may have an “aspheric portion” 2560 within approximately 3 mm to 5 mm of the discontinuity. After this portion, the mostly spherical power region may be substantially spherical. The combination of the progressive optical power region's optical power and the mostly spherical power region's aspheric portion's optical power may form a combined progressive optical power region having an optical power that increases immediately after the discontinuity in a mostly continuous manner as opposed to a sharp step up in optical power. The net optical effect is that the step in optical power is less than the full optical power 2570 provided by the mostly spherical power region. The aspheric portion and the progressive optical power region allow the full optical power of the mostly spherical power region to be achieved gradually after the discontinuity. The aspheric portion may provide a proper upper far-intermediate distance correction 2580. Alternatively, the progressive optical power region may contribute additional optical power to provide the proper upper far-intermediate distance correction. The progressive optical power region may then increase in optical power to provide a proper intermediate distance correction 2585. Alternatively, a proper far-intermediate distance correction may not be provided. The optical power of the progressive optical power region may further increase until the full near distance optical power 2590 after which it may begin to decrease again. Thus, the mostly spherical power region and the progressive optical power region may each have an incremental add power which together provide the total add power of the lens. In embodiments of the present invention a lower far-intermediate distance correction 2595 may be provided by a step down in optical power after the near distance zone. Alternatively, the lower far-intermediate distance zone may be provided by the progressive optical power region contributing negative optical power which decreases the optical power in the lens.

FIG. 26 shows the optical power along the center vertical mid-line of an embodiment of the present invention including a mostly spherical power region, a discontinuity, and a progressive optical power region connecting the far distance zone to the near distance zone. The figure is not drawn to scale. The optical power in the far distance zone is shown as piano and is therefore represented by the x-axis 2610. The discontinuity 2620 may be located below the fitting point 2630 between the far distance zone and the upper far-intermediate distance zone 2640. Alternatively, the discontinuity may be located below the fitting point between the far distance zone and the intermediate distance zone 2650. The discontinuity may be caused by the mostly spherical power region, which causes a step in optical power, and contributes an optical power 2660. The step up in optical power may be equal to the optical power needed for far-intermediate distance correction. Alternatively, the step up in optical power may be equal to the optical power needed for intermediate distance correction. The progressive optical power region may start at a portion of the mostly spherical power region, for example, immediately after the discontinuity or shortly thereafter at 2670. If the progressive optical power region begins below the discontinuity, a plateau of optical power may then be provided for either the upper far-intermediate distance zone or for the intermediate distance zone. The progressive optical power region continues until the full near distance optical power 2680 after which it may contribute negative optical power that decreases the optical power in the lens. Thus, the mostly spherical power region and the progressive optical power region may each have an incremental add power which together provide the total add power of the lens. If the optical power decreases to between approximately 20% to approximately 44% of the add power in the near distance zone, a lower far-intermediate zone may be provided. In some embodiments of the present invention, the lens may include plateaus of optical power for any of the distance zones.

In an embodiment of the present invention the lens may provide +2.00D near add power. The lens may include a buried mostly spherical power region having an optical power of +1.00D (i.e., the mostly spherical power region has an incremental add power) that is aligned so that the top edge of the mostly spherical power region is aligned approximately 3 mm below the fitting point of the lens. The lens may have a progressive optical power surface having a progressive optical power region located on the convex external surface of the lens. Alternatively, the progressive optical power surface could be located on the concave surface of the lens, split between both external surfaces of the lens, or buried within the lens. The progressive optical power region has an initial optical power of zero which increases to a maximum optical power of +1.00D (i.e., the progressive optical power region has an incremental add power). The progressive optical power region is aligned so that the start of its channel which has zero optical power begins approximately 10 mm below the fitting point of the lens. In other words, the progressive optical power region is aligned so that the start of its channel is approximately 7 mm below the discontinuity caused by the step up in optical power caused by the buried spherical power region. In this embodiment, there is no far-intermediate distance zone found in the lens. However, the intermediate distance zone has a minimum of approximately 7 mm of vertical stability of vision which is far greater than any PAL lens commercially available. As can be readily understood, the combined optical power of the progressive optical power and the mostly spherical power region does not begin until after approximately 7 mm below the top edge of the mostly spherical power region. Thus, the optical power from approximately 3 mm below the fitting to approximately 10 mm below the fitting point is the +1.00D optical power which is provided by the mostly spherical power region. This optical power is 50% of the near distance add power and therefore provides proper intermediate distance correction.

In still another embodiment of the present invention, the lens may provide +2.50D near add power. The lens may have a mostly spherical power region having an optical power of +1.25D (i.e., the mostly spherical power region has an incremental add power) which is free formed on the concave back toric/astigmatic correcting external surface of the lens that is aligned so that the top edge of the mostly spherical power region is approximately 4 mm below the fitting point of the lens. The lens may have a progressive optical power region located on the front convex surface of the lens having an initial optical power of zero which increases to a maximum optical power of +1.25D (i.e., the progressive optical power region has an incremental add power). The progressive optical power region is aligned so that the start of its channel begins approximately 10 mm below the fitting point of the lens. In other words, the progressive optical power region is aligned so that the start of its channel is approximately 6 mm below the discontinuity caused by the step up in optical power caused by the buried spherical power region. In this inventive embodiment, there is no far-intermediate distance zone found in the inventive lens. However, the intermediate distance zone has a minimum of approximately 6 mm of vertical stability of vision which is far greater than any PAL lens commercially available. As can be readily understood, the combined optical power of the progressive optical power and the mostly spherical power region does not begin until after approximately 6 mm below the top edge of the mostly spherical power region (the top edge of the mostly spherical power region being the location of the discontinuity). Thus, the optical power from approximately 4 mm below the fitting to approximately 10 mm below the fitting point is the +1.25D optical power which is provided by the mostly spherical power region. This optical power is 50% of the near distance add power and therefore provides proper intermediate distance correction.

In an embodiment of the present invention the lens may provide +2.25D near add power. The lens may include a buried mostly spherical power region having an optical power of +0.75D (i.e., the mostly spherical power region has an incremental add power) that is aligned so that the top edge of the mostly spherical power region is aligned approximately 3 mm below the fitting point of the lens. The lens may have a progressive optical power surface having a progressive optical power region located on the convex external surface of the lens. Alternatively, the progressive optical power surface could be located on the concave surface of the lens, split between both external surfaces of the lens, or buried within the lens. The progressive optical power region has an initial optical power of zero which increases to a maximum optical power of +1.50D (i.e., the progressive optical power region has an incremental add power). The progressive optical power region is aligned so that the start of its channel which has zero optical power begins approximately 7 mm below the fitting point of the lens. In other words, the progressive optical power region is aligned so that the start of its channel is approximately 4 mm below the discontinuity caused by the step up in optical power caused by the buried spherical power region. In this embodiment, there is a far-intermediate distance zone found in the lens. The far-intermediate distance zone has a minimum of approximately 4 mm of vertical stability of vision. No commercially available PAL has a far-intermediate distance zone or a far-intermediate distance zone having such a long vertical stability of vision. As can be readily understood, the combined optical power of the progressive optical power region and the mostly spherical power region does not begin until after approximately 4 mm below the top edge of the mostly spherical power region. Thus, the optical power from approximately 3 mm below the fitting to approximately 7 mm below the fitting point is the +0.75D optical power which is provided by the mostly spherical power region. This optical power is 33.33% of the near distance add power and therefore provides proper far-intermediate distance correction.

It should be pointed out that the above embodiments are provided as examples only and are not meant to limit the distances from the fitting point for the alignment of the progressive optical power region or the mostly spherical power region. In addition the optical powers given in the examples are also not meant to be limiting. Further, the location of a region being on the surface of the lens, split between surfaces of the lens, or buried within the lens should not be construed as limiting. Finally, while certain embodiments above may teach the absence of a far-intermediate distance zone, the far-intermediate distance zone can be included by altering the alignment and/or optical powers provided by each region.

As mentioned above, in embodiments of the present invention, a first optical power region having a first incremental add power may be in optical communication with a second optical power region having a second incremental add power such that the two incremental add powers are optically aligned to provide a proper near distance correction for a wearer. The incremental add powers may be provided refractively or diffractively. In other words, the optical power regions may be part of a refractive optic or a diffractive optic. The first optical power region may be a mostly spherical power region and the second optical power region may be a progressive optical power region. The mostly spherical power region may thus have a mostly spherical incremental add power and the progressive optical power region may thus have a progressive incremental add power.

In embodiments of the present invention, the mostly spherical power region may be on a surface of an ophthalmic lens or buried within the ophthalmic lens. The mostly spherical incremental add power may be in a refractive power region that generates optical power in a refractive manner. Alternatively, the mostly spherical incremental add power may be in a diffractive optical power region that generates optical power in a diffractive manner. For both refractive and diffractive optical power regions, optical power is generated by an optical interface between a first optical material and a second optical material having different indices of refraction. A refractive power region may be a section of a surface of a sphere where the optical power is defined by: φ=(n₂−n₁)/R, where φ is the optical power in diopters of the refractive power region, n₂ is the index of refraction of the first optical material, n₁ is the index of refraction of the second optical material, and R is the radius of the sphere. The refractive power region is comprised of a thickness, an index of refraction, and a curvature change.

A diffractive optical power region may be a phase-wrapped, surface relief diffractive structure comprised of concentric rings of the appropriate blaze profile. Such a structure is well-known in the art. The optical power of such a diffractive optical power region is defined by: r_(i)=[(2iλ)/φ]^(1/2), where r_(i) is the radius of the i^(th) ring (i=1, 2, 3, . . . ), λ is the design wavelength of the diffractive optical power region, and is the optical power in diopters of the diffractive optical power region. While the radii of the rings determine the optical power of the diffractive optical power region, the height, d, of the surface relief diffractive structure determines the fraction of incident light brought to focus (i.e., the diffraction efficiency of the diffractive optical power region). Maximum diffraction efficiency is achieved when the phase retardation of the diffractive optical power region is an integer number of wavelengths as defined by: (n₂−n₁)d=mλ, where n₂ is the index of refraction of the first optical material, n₁ is the index of refraction of the second optical material, d is the height of the diffractive structure, λ is the design wavelength of the diffractive optical power region, and m is an integer (m=1, 2, 3, . . . ).

In an embodiment of the present invention, a first multifocal optic having a refractive progressive optical power region may be provided. The refractive progressive optical power region may have an incremental add power of +1.00D, though any add power is possible. The first multifocal optic may be comprised of CR39 resin (trademarked by PPG) and have a refractive index of approximately 1.50, by way of example only. The first multifocal optic may be cured (by way of example only, by thermal casting) onto the surface of a second multifocal optic to form a composite lens. The second multifocal optic may have at least one mostly spherical power region having an incremental add power. The second multifocal optic may be a lens, a lens wafer, a finished lens blank, or a semi-finished lens blank. The second multifocal optic may be comprised of a cured polymer such as, by way of example only, Mitsui's MR10 which has a refractive index of approximately 1.67. The second multifocal optic may have at least one multifocal surface capable of generating more than one optical power. The multifocal surface may be on the outside of the second multifocal optic prior to being covered by the first multifocal optic.

The multifocal optic can be one of (by way of example only) a refractive executive bifocal, a refractive lined FT 28, a refractive FT 35, a refractive curve top 28, a refractive curve top 35, a refractive 7×35 trifocal, a refractive ultex bifocal, a refractive round 22 bifocal, a non-refractive (i.e., diffractive) optical power region having a surface relief diffractive pattern that is designed to provide a specific positive diopter optical power, or any other multifocal optic having a mostly spherical incremental add power region. The second multifocal optic may have any combination of optical powers.

It should be noted that in most embodiments of the present invention the mostly spherical power region having a first incremental add power is physically separated (i.e., spaced apart) from and is in optical communication with the progressive optical power region that has a second incremental add power region. The mostly spherical power region may be a buried refractive or diffractive optical power region. In other embodiments of the present invention, a first incremental add power is part of a refractive optical power region and is optically aligned and in optical communication with, but not spaced apart from (i.e., not in physical contact with) a second incremental add power that is part of a diffractive optical power region. In embodiments of the present invention, the mostly spherical power region's horizontal diameter (regardless of whether the region is diffractive or refractive) is wider than the reading zone width of the lens as defined by the progressive optical power region.

In most, but not all cases, the diffractive optical power region may provide an optical power that is within the range of +0.50D and +1.50D, though any optical power is possible. Those skilled in the art can readily design such a diffractive optic. It should be further pointed out that the optical power at or near the peripheral outer edge of either the diffractive optical power region or the lined boundary of the mostly spherical incremental add power region can be blended so as to hide the peripheral edge discontinuity of the second multifocal optic within the composite lens. Such a blend can be that of a optical power blend, optical efficiency blend, or a combination of both.

In certain embodiments of the present invention, the second multifocal optic may be provided as a semi-finished lens blank having a buried diffractive optical power region that contributes an incremental add power of +1.00D within the semi-finished blank whereby the lens blank is finished on one external surface and is unfinished on the other opposing surface of the optic. However, it should be pointed out that the incremental add power of the diffractive optical power region can be within the range of +0.25D to +1.50D. The first multifocal optic that comprises a refractive incremental add power region may be cast and cured onto the surface of the second multifocal optic that has the diffractive incremental add power region in order to form the composite optic whereby the refractive incremental add power region is spaced apart (i.e., physically separated) from the diffractive incremental add power region however both refractive and diffractive incremental add power regions are aligned to be in optical communication with one another.

In this embodiment, the diffractive incremental add power region is buried within the final composite lens, lens blank, or semi-finished lens blank. In such an embodiment, the composite lens may have an external front surface having a refractive progressive optical power region, a buried diffractive optical power region, and an unfinished external back surface capable of being free formed or surfaced and polished at a latter date. It should be noted that in certain embodiments of the invention the buried diffractive optical power region is located within a semi-finished lens blank such that during the step of free forming the semi-finished lens blank a refractive progressive optical power region is added and aligned properly to the semi-finished lens blank. This is done in such a manner that the buried diffractive optical power region is aligned and in proper optical communication with the newly added (i.e., free formed) refractive progressive optical power region. It should be noted that in another embodiment of the present invention the buried diffractive optical power region is located within an unfinished lens blank such that during the step of free forming the unfinished lens blank a refractive progressive optical power region is added and aligned properly to the unfinished lens blank. This is done in such a manner that the buried diffractive optical power region is aligned and in proper optical communication with the newly added (i.e., free formed) refractive progressive optical power region. The buried diffractive optical power region contributes optical power to the composite lens due to the index of refraction difference between the first multifocal optic material composition and the second multifocal optic material composition.

It is to be understood that while in this specific embodiment of the present invention the first multifocal optic comprises a material having an index of refraction of approximately 1.50 and the second multifocal optic comprises a material having an index of refraction of approximately 1.67, the material for each optic may be reversed and for that mater can be of any index of refraction so long as the two materials have two different indices of refraction.

Embodiments of the present invention may be described in terms of a mostly spherical power region. However, it is to be understood that since a diffractive optical power region is a type of mostly spherical incremental add power region, these embodiments also describe embodiments of the present invention that include a diffractive optical power region. Thus, the size, shape, and optical design of the diffractive optical power region may be the same as the size, shape, and optical design of a mostly spherical power region as described by embodiments of the present invention. Similarly, the alignment of the diffractive optical power region relative to the progressive optical power region may be the same as the alignment of a mostly spherical power region relative to a progressive optical region as described by embodiments of the present invention.

In another embodiment of the present invention, a lined bifocal may be the second multifocal optic. The multifocal surface of the lined bifocal may be buried within the composite lens. In this embodiment, the refractive curves of the lined bifocal may be designed to allow for the proper additive power needed given the index of refraction of the material used for the second multifocal optic and the index of refraction of the material used for the first multifocal optic. In most, but not all cases, the add power contribution (i.e., the incremental add power) of the second multifocal optic may be one of +0.25D, +0.50D, +0.75D, +1.00D, +1.25D, and in some cases +1.50D or any optical power within the range of +0.25D and +1.50D. In most, but not all cases, the far distance optical power of the second multifocal optic is zero optical power. The optical power contribution of the refractive progressive optical region on the first multifocal optic may provide the far distance optical power correction for the wearer and an incremental add power contribution that is in most cases, but not all, one +0.75D, +1.00D, +1.25D, and +1.50D or any optical power within the range of +0.75D and +1.50D.

In still other embodiments of the present invention, the external back surface of the composite lens may be finished. When the external back surface of the composite lens is finished, the back surface may provide the needed posterior curvatures to provide at least part of the correction of the wearer's far distance, intermediate distance, and/or near distance vision. Thus, the composite lens may be capable of correcting the wearer's refractive error such as the wearer's astigmatism, hyperopia, myopia, and/or presbyopia. When the back surface is unfinished (e.g., the second multifocal optic is a semi-finished blank) the composite lens will not have a final finished optical power. It should be pointed out that it is possible to freeform the appropriate refractive curvature on one or both of the external surfaces of the lens.

In another embodiment of the present invention, a thin optical wafer having a multifocal surface may be buried within a cavity filled with an uncured resin to form a composite lens when the resin is cured. Thus, the resin may form both external surfaces of the composite lens once the resin is cured. The multifocal surface may generate an optical power either refractively or diffractively. The resin will have an index of refraction that is different than the index of refraction of the thin optical wafer. One of the surfaces of the uncured resin, once cured, may form a refractive progressive optical power region (or for that mater any desired refractive optical power region) having an external surface curvature. The resin may be cured by one of a thermal cure, a photo cure (visible or invisible), or a combination of a photo cure and a thermal cure, for example. The optical wafer may be held in position, by way of example only, by a gasket used in the casting process.

In another embodiment of the present invention, a first thin optic may have a progressive optical power region on its surface. This first thin optic can be preformed or can be formed in situ by way of casting or molding. Such casting or molding methods are well known and can be a thermal cure, a photo cure, or a combination of both. The first thin optic will have a known index of refraction. The first thin optic may be formed on top of a different thin layer of a prefabricated optical material (a second optical perform) having a different index of refraction from the thin optic to form a composite optic. When both the first thin optic and the second optical perform are both preformed they may be adhesively bonded to one another. When the first thin optic is formed in situ it can be cast directly onto the second optical perform. The second preform may have a mostly spherical power region that provides an incremental add power region that generates optical power either refractively or diffractively. The newly formed composite optic may be adhesively bonded to a thicker non-finished lens blank to form a composite lens having an external surface having a refractive progressive optical power region, a buried mostly spherical power region, and an unfinished external surface capable of being finished by fabrication techniques known in the art.

In most embodiments of the present invention, but not all, the optical perform that comprises the mostly spherical incremental add power region may be used as an integral consumable back mold that is placed in the back of an optical gasket used for casting ophthalmic lenses. The term “integral consumable” is used to denote that the lens or optic is used both as a mold to form the back of the composite lens, but also that the lens or optic is consumed and becomes bonded to the portion of the composite lens being cured within the mold, thus becoming an integral part of the final composite lens. The front mold may be provided by way of a glass or metal mold that is utilized in casting ophthalmic lenses. The cavity formed between the front mold and the back consumable mold may be filled with an optical resin having the proper index of refraction and cured. The curing may be one of a thermal curing, a light curing, or a combination of both depending upon the initiator needed and the material to be cured, for example. In this embodiment of the invention the surface of the optical perform comprising the mostly spherical incremental add power region is placed facing the uncured resin layer having a different index of refraction which will then bond to the surface of the optical perform comprising the mostly spherical incremental add power region. Upon curing, this interface will form an interface where the two different indices of refraction of the materials meet. This index of refraction mismatch allows for the appropriate buried incremental add power to be provided.

In embodiments of the present invention, the molding technique just described may allow for the fabrication of either semi-finished or finished lens blanks. When casting the composite lens as a finished lens blank, the consumable back mold may be prefabricated with the appropriate toric curves on its external back surface so as to correct for the wearer's astigmatic refractive error. The consumable back mold may then be rotated within the gasket to allow for aligning the astigmatic axis relative to the front surface mold that forms the progressive optical power region's curvature in the composite lens. The technique of setting the axis of astigmatic correction is well known in the art of finished ophthalmic lens casting.

In still another embodiment of the present invention, a front integral consumable mold being made of optical plastic material (also that of an optical perform) may be used. The front integral consumable mold, or optical perform, may be preformed having a refractive progressive optical power region curvature on its external surface and a spherical power region that generates optical power either refractively or diffractively on its internal back surface. In this case, a glass or metal mold may be used on the back to form the cavity which is to be filled with a resin and then cured to form a composite lens. The front consumable mold in this case may become integral with the cured resin optic that is formed. Following this, the back of the composite lens could be free formed or ground and polished. Also, as discussed before, the back surface of the composite lens could be molded upon curing into a finished surface that provides the necessary toric curvature needed to correct the astigmatism of the intended wearer and/or provide the proper spherical power needed for the wearer's far distance optical power correction as well as the wearer's near distance optical power correction. When an optical perform is used as a consumable mold the surface that faces the uncured resin may be the buried incremental add power region (which can be refractive or diffractive). Furthermore, the indices of refraction of the optical preform and the resin or newly cured layer are of different values.

FIGS. 29A-29D show methods of manufacturing a composite semi-finished lens blank according to embodiments of the present invention. FIG. 29A shows a method of manufacturing a composite lens including casting a preformed diffractive multifocal optic having a diffractive optical power region and having a known index of refraction, followed by casting a layer of a different index of refraction that comprises the progressive optical power region's curvature on top of the diffractive multifocal optic. In this embodiment, the diffractive optical power region is configured to be that of the mostly spherical incremental add power region. FIG. 29B shows the same method of manufacturing as FIG. 29A with the exception of using a different front casting ophthalmic material. FIG. 29C shows a method of manufacturing a composite lens including encapsulating a preformed diffractive multifocal optic (also referred to as a preformed optical insert) having a known index of refraction and a diffractive optical power region between a front progressive optical power region and a back additional layer of ophthalmic material having a different index of refraction whereby the material of the front progressive optical power region and the back additional layer are the same, however the material of the diffractive multifocal optic is different. FIG. 29D shows the same method of manufacturing as FIG. 29C with the exception of the diffractive multifocal optic material being cast from a different ophthalmic material (such as a different material manufacturer) than the diffractive multifocal optic in FIG. 29C. It should be further pointed out that the semi-finished lens blank as illustrated herein can be either surfaced or free formed to be that of a finished lens or a finished lens blank. In addition, the lens can be made by being fully molded to the final finished lens shape and design by using the appropriate resin, mold or molds, and optical perform combinations.

Table I is a listing of various ophthalmic materials, any two of which can be utilized to make the composite lens provided the two materials are either compatible and will bond to one another or a coating is used to promote adhesion between the two materials.

TABLE I Material Ref. Index Abbe Value Supplier CR39 1.498 55 PPG Nouryset 200 1.498 55 Great Lakes Rav-7 1.50 58 Evergreen/Great Lakes Co. Trivex 1.53 44 PPG MR-8 1.597 41 Mitsui MR-7 1.665 31 Mitsui MR-10 1.668 31 Mitsui MR-20 1.594 43 Mitsui Brite-5 1.548 38 Doosan Corp. (Korea) Brite-60 1.60 35 Doosan Corp. (Korea) Brite-Super 1.553 42 Doosan Corp. (Korea) TS216 1.59 32 Tokuyama Polycarbonate 1.598 31 GE

In certain embodiments of the invention a blend zone transitions the optical power between at least a portion of the mostly spherical power region and the far distance zone. FIGS. 27A-27C show embodiments of the present invention having a blend zone 2710 with a substantially constant width located at or below a fitting point 2720. FIGS. 28A-28C shows embodiments of the present invention having a blend zone 2810 including a portion with a width of substantially 0 mm (thereby providing a transition in this portion similar to a lined bifocal) located at or below a fitting point 2820. FIG. 27A and FIG. 28A show the top edge of the blend zone located at the fitting point. FIG. 27B and FIG. 28B show the top edge of the blend zone located 3 mm below the fitting point. FIG. 27C and FIG. 28C show the top edge of the blend zone located 6 mm below the fitting point. Portions of blend zone 2710 and 2810 may be less than approximately 2.0 mm wide and may be between approximately 0.5 mm wide and approximately 1.0 mm wide. It should be noted, that embodiments of the present invention contemplate using a blend zone having a width between approximately 0.1 mm and approximately 1.0 mm. FIG. 28A further shows a central region of the blend zone corresponding to the location of the fitting point that has a width between approximately 0.1 mm and approximately 0.5 mm. FIG. 28C shows blend zone 2810 reducing in width to having no blend in the central region of the blend zone.

The mostly spherical power region and the far distance zone each have an optical power that may be defined by a specific optical phase profile. To create a blend zone of a given width, a phase profile is generated that, in certain embodiments of the present invention, matches the value and first spatial derivative of the phase profile of a first optical power region at the start of the blend zone and matches the value and first spatial derivative of the phase profile of a second optical power region at the end of the blend zone. In other embodiments of the invention the start and end of the blend zone phase profile match the value as well as the first and second spatial derivatives of the phase profiles of the first and second optical power regions, respectively. In either case, the phase profile of the blend zone may be described by one or more mathematical functions and/or expressions that may include, but are not limited to, polynomials of second order or higher, exponential functions, trigonometric functions, and logarithmic functions. In certain embodiments of the present invention the blend zone is diffractive, in other embodiments of the present invention the blend zone is refractive and in still other embodiments of the present invention the blend zone has both refractive and diffractive sub-zones.

In some embodiments of the present invention in order for the lens to provide high quality vision, the width of the blend zone must be quite narrow. The blend zone must be narrow to allow the wearer's eye to traverse the blend zone quickly as the wearer's line of sight switches between a far distance focus and an intermediate distance or near distance focus. For example, the width of the blend zone may be less than approximately 2.0 mm, less than approximately 1.0 mm, or less than approximately 0.5 mm. Fabrication of such a narrow blend zone is very difficult using conventional ophthalmic lens fabrication techniques. For example, current state-of-the-art single point, free-forming ophthalmic surface generation only permits blend zones having a width in excess of approximately 0.5 mm. Furthermore, these methods provide little or no control over the exact shape of the blend zone profile. The generation of conventional glass mold tooling for casting lenses from liquid monomer resins is also limited, as glass cannot be single point machined and must be worked with a grinding process where all fine surface features would be lost.

Currently, the only method available to generate lenses with a narrow blend zone having a known and well-controlled profile in an economically feasible manner is the single point diamond turning of metal lens molds. In such a method the diamond tooling equipment is outfitted with either slow or fast tool servo capabilities, both of which are well known in the art. Such molds can be generated, by way of example only, in materials such as electrolytic Ni or CuNi and may be used in either a liquid monomer resin casting process or a thermoplastic injection molding process.

Each of the above embodiments can be fabricated using diamond turning, free forming, surface-casting, whole-lens casting, laminating, or molding (including injection molding). It has been found that in embodiments without a blend zone, diamond turning provides for the sharpest discontinuity and the best fidelity. In most, but not all cases, molds are diamond turned from metal such as, by way of example only, nickel coated aluminum or steel, or copper nickel alloys. Fabrication methods or techniques needed to produce the steps in optical power are known in the industry and consist, by way of example only, of diamond turning molds or inserts and then casting or injection molding the lens, diamond turning the actual lens, and free forming.

In an embodiment of the present invention, by utilizing state-of-the-art free-forming fabrication techniques it is possible to place the toric surface that corrects the wearer's astigmatic refractive error on the same surface of the lens as the mostly spherical power region. When these two different surface curves are generated by free forming it is then possible to place the progressive optical power region on the opposite surface of the lens. In this case the progressive optical power region is molded and pre-formed on one surface of the semi-finished blank and the combined astigmatic correction and spherical power region is provided by way of free-forming the opposite unfinished surface of the semi-finished blank.

In some embodiments of the present invention, the mostly spherical power region is wider than the narrowest portion of the channel bounded by an unwanted astigmatism that is above approximately 1.00D. In other embodiments of the present invention, the mostly spherical power region is wider than the narrowest portion of the channel bounded by an unwanted astigmatism that is above approximately 0.75D.

In some embodiments of the present invention the mostly spherical power region may be substantially spherical or may be aspheric as well; for example, to correct for astigmatism. The mostly spherical power region may also have an aspheric curve or curves placed to improve the aesthetics of the lens or to reduce distortion. In some embodiments of the present invention, the inventive multifocal lens is static. In other embodiments of the present invention, the inventive multifocal lens is dynamic and the mostly spherical power region is produced dynamically by, for example, an electro-active element. In some embodiments of the present invention, the mostly spherical power region is an embedded diffractive element such as a surface relief diffractive element.

Embodiments of the present invention contemplate the production of semi-finished lens blanks where one finished surface comprises the mostly spherical power region, far distance zone and blend zone, and the other surface is unfinished. Also contemplated is the production of semi-finished lens blanks where one finished surface comprises the progressive optical power region, and the other surface is unfinished. Also contemplated is that for certain prescriptions a finished lens blank is produced. It should also be noted that optimizing the progressive optical power region relative to the mostly spherical power region to optimize the level of unwanted astigmatism, the channel length, and the channel width is also contemplated. In addition, it is contemplated to optimize the blend zone, if desired, to further reduce the unwanted astigmatism found in the blend zone. Furthermore, any lens materials may be used whether plastic, glass, resin, or a composite. Also contemplated is the use of any optically useful index of refraction. All coatings and lens treatments that would normally be used on ophthalmic lenses such as, by way of example only, a hard scratch resistant coating, an anti-refraction coating, a cushion coating, and a self-cleaning Teflon coating may be used. Finally, embodiments of the present invention may be fabricated by techniques known in the art including, but not limited to, surfacing, free-forming, diamond turning, milling, stamping, injection molding, surface casting, laminating, edging, polishing, and drilling.

Embodiments of the present invention may be used to produce contact lenses and spectacle lenses.

In order to more clearly show the superiority of the inventive multifocal lens over conventional state-of-the-art PALs, an embodiment of the present invention was compared to two state-of-the-art PALs. Measurements of the lenses were taken from a Visionix VM-2500™ lens mapper, trademarked by Visionix. One of the state-of-the-art PALs is a Varilux Physio™ lens, trademarked by Varilux, having approximately +2.00D add power. The other state-of-the-art PAL is a Varilux Ellipse™ lens, trademarked by Varilux, which has a short channel design and approximately +2.00D add power. As can be seen in Table II, the Physio lens has a maximum unwanted astigmatism of 1.68D, a channel width of 10.5 mm, and a channel length of 17.0 mm. The Ellipse lens has a maximum unwanted astigmatism of 2.00D, a channel width of 8.5 mm, and a channel length of 13.5 mm. The inventive lens also has an add power of approximately +2.00. However, in comparison, the inventive less has a maximum unwanted astigmatism of less than 1.00D. Because the maximum unwanted astigmatism is below 1.00D, the channel width is for all intents and purposes as wide as the lens itself. Lastly, the channel length is 14.5 mm. It should also be pointed out, that neither the Visionix VM-2500™ lens mapper nor the Rotlex Class Plus™ lens mapper were able to detect unwanted astigmatism at the discontinuity in the inventive lens due to its small width.

TABLE II VARILUX ELLIPSE VARILUX PHYSIO INVENTION EMBODIMENT ATTRIBUTE (2.00 D ADD) (2.00 D ADD) (1 D SPHLENS + 1 D ADD PHYSIO) DISTANCE POWER 0.12 D .O8 D −0.11 D NEAR TOTAL POWER 2.11 D 2.17 D 1.90 D TOTAL ADD POWER 1.99 D 2.11 D 2.02 D CHANNEL LENGTH 13.5 MM 17.0 MM 14.5 MM CHANNEL WIDTH 8.5 MM 10.5 MM 23.5 MM MAX UNWANTED ASTIGMATISM 2.05 D 1.68 D 0.90 D (BELOW THE MIDLINE) MAX UNWANTED ASTIGMATISM 0.98 D 0.95 D 0.5 D (ABOVE THE MIDLINE) 

1. A lens comprising: a first layer having a first index of refraction, wherein the first layer has a first curvature and a second curvature, wherein the second curvature provides a single optical power; and a second layer having a second index of refraction different from the first index of refraction, wherein the second layer has a first curvature and a second curvature, wherein the second curvature of the second layer provides a progression of optical power and is in optical communication with the second curvature of the first layer for providing a combined optical power for correcting near distance vision.
 2. The lens of claim 1, wherein the single optical power is a spherical optical power.
 3. The lens of claim 1, wherein the second curvature of the second layer is formed on an external surface of the lens.
 4. The lens of claim 1, wherein the second curvature of the first layer begins 4 millimeters below a fitting point of the lens.
 5. The lens of claim 1, wherein there is a discontinuity in the optical power of the lens between the first and second curvatures of the first layer.
 6. The lens of claim 1, wherein the first layer comprises a far distance zone and a first optical element and the second layer comprises a far distance zone and a second optical element, wherein the first optical element comprises a substantially spherical optical power region, the substantially spherical optical power region contributing a first portion of a total near distance add power of the lens, wherein an optical discontinuity occurs at a boundary of the first optical element and the far distance zone of the first layer due to a step-up in optical power between the first optical element and the far distance zone of the first layer, wherein the first optical element is located 4 millimeters below a fitting point of the lens, wherein the second optical element comprises a progressive optical power region, the progressive optical power region contributing a second portion of the total near distance add power of the lens, and wherein the first and second optical elements are in optical communication such that the first portion of the total near distance add power of the lens and the second portion of the total near distance add power of the lens are combined to provide the total near distance add power of the lens.
 7. The lens of claim 6, wherein the first and second optical elements are aligned to form a far-intermediate distance zone and an intermediate distance zone.
 8. The lens of claim 7, wherein the far-intermediate distance zone has an add power between approximately 20% and approximately 44% of the total near distance add power of the lens and the intermediate distance zone has an add power between approximately 45% and approximately 55% of the total near distance add power of the lens. 